Cell cycle

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Cell cycle

Michael Kallsen

Michael Kallsen

Autosomal trisomies: Pathology review
Down syndrome (Trisomy 21)
Inheritance patterns
DNA damage and repair
DNA replication
Free radicals and cellular injury
Cell cycle
Selective permeability of the cell membrane
Colorectal polyps and cancer: Pathology review
Endometrial hyperplasia and cancer: Clinical
Lung cancer
Metaplasia and dysplasia
Oral cancer
Testicular cancer
Breast cancer: Pathology review
Hypertension: Pathology review
Apnea, hypoventilation and pulmonary hypertension: Pathology review
Acute respiratory distress syndrome
Angina pectoris
Aortic valve disease
Arterial disease
Asthma
Atrial septal defect
Bronchiectasis
Chronic bronchitis
Chronic venous insufficiency
Coarctation of the aorta
Deep vein thrombosis
Emphysema
Endocarditis
Gas exchange in the lungs, blood and tissues
Heart failure
Mitral valve disease
Myocardial infarction
Patent ductus arteriosus
Pericarditis and pericardial effusion
Peripheral artery disease
Pleural effusion
Pneumonia
Pulmonary edema
Restrictive lung diseases
Shock
Stroke volume, ejection fraction, and cardiac output
Tetralogy of Fallot
Dementia: Pathology review
Anxiety disorders: Clinical
Arteriovenous malformation
Bipolar and related disorders
Cauda equina syndrome
Cranial nerves
Seizures and epilepsy
Generalized anxiety disorder
Headaches: Pathology review
Huntington disease
Ischemic stroke
Major depressive disorder
Meningitis
Migraine
Multiple sclerosis
Myasthenia gravis
Panic disorder
Parkinson disease
Stroke: Clinical
Alzheimer disease
Diabetes mellitus: Pathology review
Abnormal uterine bleeding: Clinical
Adrenocorticotropic hormone
Chlamydia trachomatis
Cortisol
Cushing syndrome
Endometriosis
Glucagon
Glucocorticoids
Herpes simplex virus
HIV (AIDS)
Hyperthyroidism: Pathology review
Hypothyroidism: Pathology review
Hypothyroidism
Neisseria gonorrhoeae
Pelvic inflammatory disease
Polycystic ovary syndrome
Primary adrenal insufficiency
Syndrome of inappropriate antidiuretic hormone secretion (SIADH)
Testosterone
Thyroid hormones
Benign prostatic hyperplasia
Anemia of chronic disease
Chronic leukemia
Coagulation disorders: Pathology review
Disseminated intravascular coagulation
Factor V Leiden
Hemophilia
Hodgkin lymphoma
Non-Hodgkin lymphoma
Hypocalcemia
Hypokalemia
Inflammation
Innate immune system
Introduction to the immune system
Iron deficiency anemia
Leukemias: Pathology review
Platelet disorders: Pathology review
Sickle cell disease (NORD)
Type IV hypersensitivity
Acute cholecystitis
Acute pancreatitis
Acute pyelonephritis
Alcohol-associated liver disease
Appendicitis
Autoimmune hepatitis
Biliary colic
Bowel obstruction
Celiac disease
Chronic cholecystitis
Chronic pyelonephritis
Chronic pancreatitis
Cirrhosis
Congenital disorders: Clinical
Crohn disease
Gastroesophageal reflux disease (GERD)
Irritable bowel syndrome
Lower urinary tract infection
Nephrotic syndromes: Pathology review
Peptic ulcer
Renal failure: Pathology review
Ulcerative colitis
Urinary tract infections: Pathology review
Viral hepatitis
Acne vulgaris
Atopic dermatitis
Back pain: Pathology review
Bone disorders: Pathology review
Burns
Osteoarthritis
Osteoporosis
Paget disease of bone
Psoriasis
Rheumatoid arthritis
Skin cancer
Varicella zoster virus

Transcript

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Content Reviewers

Rishi Desai, MD, MPH

The cell cycle refers to the events that somatic cells - which includes all of the cells in our bodies except the reproductive cells - go through from the moment they’re formed until the moment they divide in two identical daughter cells.

This cycle varies in length depending on the type of cell - for rapidly dividing cells, like skin cells, it takes less than a day, whereas for other cells, like liver cells, the cell cycle can last years.

The cell cycle has two phases: interphase, and mitosis.

Interphase the longest part of the cell cycle, and it’s a state of preparation, during which the cell carries out its cell functions, grows and replicates its DNA to prepare for mitosis - or cellular division.

After a parent cell divides, each of the two daughter cells enter interphase again.

Now, interphase can further be broken down in three subphases: G1, S, and G2. G1 stands for “gap” or “growth” 1, and it’s the longest phase of the cell cycle.

During G1, the cell mostly grows and the organelles take care of regular cellular business - like the synthesizing proteins and producing energy.

Inside the cell nucleus, there’s our DNA, organized as chromosomes - and during G1, each chromosome is made up of a single, thin spaghetti of DNA, called a chromatid.

At the end of G1, there’s a cell cycle control point called the G1 checkpoint - where the cell checks to see if the DNA is not damaged, and it synthesized the right proteins in the correct amount.

If it turns out that there is any reason for the cell not to divide - such as DNA damage, things can go one of two ways: the cell can either enter a non-dividing state, called the G0 phase, where the DNA repair mechanisms try to fix the problem, or the cell can self-destruct in a process called apoptosis.

Now, if the cell does get the go-ahead at the G1 checkpoint, it enters the S phase. S stands for “synthesis”, because during this phase, DNA is replicated, so that each daughter cell receives identical copies of the genetic material.

So for each chromosome from G1, an identical copy is created.

This happens with the help of a number of proteins, both structural proteins and enzymes, as well as energy.

Now, just to be clear - this doesn’t mean that the number of chromosomes increases - human somatic cells have 46 chromosomes throughout the cell cycle.

However, the amount of DNA they have - and, in turn, their aspect - changes throughout the cell cycle.

So each chromosome enters the S phase with a single copy of the genetic information, called a chromatid.

During replication, each chromatid is copied and pasted, so the amount of DNA doubles up.

The two resulting chromatids are identical to each other and to the original genetic template, and they join together in the center in a region called the centromere - - but they still make up a single chromosome.

So while the amount of genetic information has doubled, there are still 46 chromosomes that contain that genetic information.

The cell can now enter the G2 phase. G2 stands for “gap” or “growth” 2.

Even after synthesizing copies of the DNA, the cell still has to duplicate organelles so that there are enough for both daughter cells.

In fact, by the end of G2, the cell looks like a big balloon of cytoplasm and organelles, just waiting to split.

Key Takeaways

The cell cycle is a process that somatic cells go through that involves the duplication of DNA, growth, and division of the cell. The cell cycle can be divided into four phases: G1, S, G2, and M. G1 is the growth phase, where the cell performs all of its functions, and S is the synthesis phase, where DNA replication occurs. G2 is the growth phase, where the cell grows in size and prepares for Mitotic division, and M is the mitotic cell division phase, dividing the cell into two identical daughter cells.