Early-onset Alzheimer’s disease occurs between a person’s 30s to mid-60s and represents less than 10 percent of all people with Alzheimer’s. Some cases are caused by an inherited change in one of three genes, resulting in a type known as early-onset familial Alzheimer’s disease, or FAD. For other cases of early-onset Alzheimer’s, research suggests there may be a genetic component related to factors other than these three genes.

A child whose biological mother or father carries a genetic mutation for early-onset FAD has a 50/50 chance of inheriting that mutation. If the mutation is in fact inherited, the child has a very strong probability of developing early-onset FAD.

Early-onset FAD is caused by any one of a number of different single-gene mutations on chromosomes 21, 14, and 1. Each of these mutations causes abnormal proteins to be formed. Mutations on chromosome 21 cause the formation of abnormal amyloid precursor protein (APP). A mutation on chromosome 14 causes abnormal presenilin 1 to be made, and a mutation on chromosome 1 leads to abnormal presenilin 2.

Each of these mutations plays a role in the breakdown of APP, a protein whose precise function is not yet fully understood. This breakdown is part of a process that generates harmful forms of amyloid plaques, a hallmark of the disease.

Critical research findings about early-onset Alzheimer's have helped identify key steps in the formation of brain abnormalities typical of the more common late-onset form of Alzheimer's. Genetics studies have helped explain why the disease develops in people at various ages.

NIA-supported scientists are continuing research into early-onset disease through the Dominantly Inherited Alzheimer Network (DIAN), an international partnership to study families with early-onset FAD. By observing the Alzheimer's-related brain changes that occur in these families long before symptoms of memory loss or cognitive issues appear, scientists hope to gain insight into how and why the disease develops in both its early- and late-onset forms.

Alzheimer’s disease is a brain disorder that slowly destroys memory and thinking skills, and, eventually, the ability to carry out the simplest tasks. In most people with Alzheimer’s, symptoms first appear later in life. Estimates vary, but experts suggest that more than 6 million Americans, most of them age 65 or older, may have dementia caused by Alzheimer’s.

Alzheimer’s disease is currently ranked as the sixth leading cause of death in the United States, but recent estimates indicate that the disorder may rank third, just behind heart disease and cancer, as a cause of death for older people.

Alzheimer’s is the most common cause of dementia among older adults. Dementia is the loss of cognitive functioning—thinking, remembering, and reasoning—and behavioral abilities to such an extent that it interferes with a person’s daily life and activities. Dementia ranges in severity from the mildest stage, when it is just beginning to affect a person’s functioning, to the most severe stage, when the person must depend completely on others for basic activities of daily living.

The causes of dementia can vary, depending on the types of brain changes that may be taking place. Other dementias include Lewy body dementia, frontotemporal disorders, and vascular dementia. It is common for people to have mixed dementia—a combination of two or more types of dementia. For example, some people have both Alzheimer’s disease and vascular dementia.

Alzheimer’s disease is named after Dr. Alois Alzheimer. In 1906, Dr. Alzheimer noticed changes in the brain tissue of a woman who had died of an unusual mental illness. Her symptoms included memory loss, language problems, and unpredictable behavior. After she died, he examined her brain and found many abnormal clumps (now called amyloid plaques) and tangled bundles of fibers (now called neurofibrillary, or tau, tangles).

These plaques and tangles in the brain are still considered some of the main features of Alzheimer’s disease. Another feature is the loss of connections between nerve cells (neurons) in the brain. Neurons transmit messages between different parts of the brain, and from the brain to muscles and organs in the body.

How Does Alzheimer's Disease Affect the Brain?

Scientists continue to unravel the complex brain changes involved in the onset and progression of Alzheimer’s disease. It seems likely that changes in the brain may begin a decade or more before memory and other cognitive problems appear. During this preclinical stage of Alzheimer’s disease, people seem to be symptom-free, but toxic changes are taking place in the brain. Abnormal deposits of proteins form amyloid plaques and tau tangles throughout the brain. Once-healthy neurons stop functioning, lose connections with other neurons, and die. Many other complex brain changes are thought to play a role in Alzheimer’s, too.

The damage initially appears to take place in the hippocampus and the entorhinal cortex, parts of the brain essential in forming memories. As more neurons die, additional parts of the brain are affected and begin to shrink. By the final stage of Alzheimer’s, damage is widespread, and brain tissue has shrunk significantly.

Signs and Symptoms of Alzheimer's Disease

Memory problems are typically one of the first signs of cognitive impairment related to Alzheimer’s disease. Some people with memory problems have a condition called mild cognitive impairment (MCI). In MCI, people have more memory problems than normal for their age, but their symptoms do not interfere with their everyday lives. Movement difficulties and problems with the sense of smell have also been linked to MCI. Older people with MCI are at greater risk for developing Alzheimer’s, but not all of them do. Some may even go back to normal cognition.

The first symptoms of Alzheimer’s vary from person to person. For many, decline in non-memory aspects of cognition, such as word-finding, vision/spatial issues, and impaired reasoning or judgment, may signal the very early stages of Alzheimer’s disease. Researchers are studying biomarkers (biological signs of disease found in brain images, cerebrospinal fluid, and blood) to detect early changes in the brains of people with MCI and in cognitively normal people who may be at greater risk for Alzheimer’s. Studies indicate that such early detection is possible, but more research is needed before these techniques can be used routinely to diagnose Alzheimer’s disease in everyday medical practice.

Stages of Alzheimer's Disease

Mild Alzheimer’s Disease

As Alzheimer’s disease progresses, people experience greater memory loss and other cognitive difficulties. Problems can include wandering and getting lost, trouble handling money and paying bills, repeating questions, taking longer to complete normal daily tasks, and personality and behavior changes. People are often diagnosed in this stage.

Moderate Alzheimer’s Disease

In this stage, damage occurs in areas of the brain that control language, reasoning, sensory processing, and conscious thought. Memory loss and confusion grow worse, and people begin to have problems recognizing family and friends. They may be unable to learn new things, carry out multistep tasks such as getting dressed, or cope with new situations. In addition, people at this stage may have hallucinations, delusions, and paranoia and may behave impulsively.

Severe Alzheimer’s Disease

Ultimately, plaques and tangles spread throughout the brain, and brain tissue shrinks significantly. People with severe Alzheimer’s cannot communicate and are completely dependent on others for their care. Near the end, the person may be in bed most or all of the time as the body shuts down.

What Causes Alzheimer’s Disease?

In recent years, scientists have made tremendous progress in better understanding Alzheimer’s and the momentum continues to grow. Still, scientists don’t yet fully understand what causes Alzheimer’s disease in most people. In people with early-onset Alzheimer’s, a genetic mutation may be the cause. Late-onset Alzheimer’s arises from a complex series of brain changes that may occur over decades. The causes probably include a combination of genetic, environmental, and lifestyle factors. The importance of any one of these factors in increasing or decreasing the risk of developing Alzheimer’s may differ from person to person.

The Basics of Alzheimer’s Disease

Scientists are conducting studies to learn more about plaques, tangles, and other biological features of Alzheimer’s disease. Advances in brain imaging techniques allow researchers to see the development and spread of abnormal amyloid and tau proteins in the living brain, as well as changes in brain structure and function. Scientists are also exploring the very earliest steps in the disease process by studying changes in the brain and body fluids that can be detected years before Alzheimer’s symptoms appear. Findings from these studies will help in understanding the causes of Alzheimer’s and make diagnosis easier.

One of the great mysteries of Alzheimer’s disease is why it largely affects older adults. Research on normal brain aging is exploring this question. For example, scientists are learning how age-related changes in the brain may harm neurons and affect other types of brain cells to contribute to Alzheimer’s damage. These age-related changes include atrophy (shrinking) of certain parts of the brain, inflammation, blood vessel damage, production of unstable molecules called free radicals, and mitochondrial dysfunction (a breakdown of energy production within a cell).

Alzheimer's Disease Genetics

Most people with Alzheimer’s have the late-onset form of the disease in which symptoms become apparent in their mid-60s or later. Researchers have not found a specific gene that directly causes late-onset Alzheimer’s, but having a form of the apolipoprotein E (APOE) gene increases a person’s risk. This gene has several forms, and one of those, APOE ε4, increases a person’s risk of developing Alzheimer’s and is also associated with an earlier age of disease onset. However, carrying the APOE ε4 form of the gene does not mean that a person will definitely develop the disease, and some people with no APOE ε4 may also develop Alzheimer’s.

Scientists also have identified several regions of interest in the genome (an organism’s complete set of DNA) that may increase or decrease a person’s risk for late-onset Alzheimer’s to varying degrees.

Early-onset Alzheimer’s occurs between a person’s 30s and mid-60s and represents less than 10% of all people with Alzheimer’s. Some cases are caused by an inherited change in one of three genes. For others, research shows that other genetic components are involved.

Most people with Down syndrome develop Alzheimer’s. This may be because people with Down syndrome have an extra copy of chromosome 21, which contains the gene that generates harmful amyloid.

Health, Environmental, and Lifestyle Factors

Research suggests that a host of factors beyond genetics may play a role in the development and course of Alzheimer’s disease. There is a great deal of interest, for example, in the relationship between cognitive decline and vascular conditions such as heart disease, stroke, and high blood pressure, as well as metabolic conditions such as diabetes and obesity. Ongoing research will help us understand whether and how reducing risk factors for these conditions may also reduce the risk of Alzheimer’s.

A nutritious diet, physical activity, social engagement, and mentally stimulating pursuits have all been associated with helping people stay healthy as they age. These factors might also help reduce the risk of cognitive decline and Alzheimer’s. Researchers are testing some of these possibilities in clinical trials.

How Is Alzheimer’s Disease Diagnosed?

Doctors use several methods and tools to help determine whether a person who is having memory problems has “possible Alzheimer’s dementia” (dementia may be due to another cause) or “probable Alzheimer’s dementia” (no other cause for dementia can be found).

To diagnose Alzheimer’s, doctors may:

• Ask the person and a family member or friend questions about overall health, use of prescription and over-the-counter medicines, diet, past medical problems, ability to carry out daily activities, and changes in behavior and personality
• Conduct tests of memory, problem solving, attention, counting, and language
• Carry out standard medical tests, such as blood and urine tests, to identify other possible causes of the problem
• Perform brain scans, such as computed tomography (CT), magnetic resonance imaging (MRI), or positron emission tomography (PET), to rule out other possible causes for symptoms

These tests may be repeated to give doctors information about how the person’s memory and other cognitive functions are changing over time.

People with memory and thinking concerns should talk to their doctor to find out whether their symptoms are due to Alzheimer’s or another cause, such as stroke, tumor, Parkinson’s disease, sleep disturbances, side effects of medication, an infection, or another type of dementia. Some of these conditions may be treatable and possibly reversible.

If the diagnosis is Alzheimer’s, beginning treatment as early as possible in the disease process could help preserve daily functioning for a while. An early diagnosis also helps families plan for the future. They can take care of financial and legal matters, address potential safety issues, learn about living arrangements, and develop support networks.

In addition, an early diagnosis provides people with more opportunities to participate in clinical trials or other research studies testing possible new treatments for Alzheimer’s.

How Is Alzheimer’s Disease Treated?

Alzheimer’s is complex, and it is therefore unlikely that any one drug or other intervention will successfully treat it in all people living with the disease.

Scientists are exploring many avenues to delay or prevent the disease as well as to treat its symptoms. In ongoing clinical trials, scientists are developing and testing several possible interventions. Under study are drug therapies aimed at a variety of disease interventions, as well as nondrug approaches such as physical activity, diet, cognitive training, and combinations of these. Just as we have many treatments for heart disease and cancer, we will likely need many options for treating Alzheimer’s. Precision medicine — getting the right treatment to the right person at the right time — will likely play a major role.

Current approaches to treating Alzheimer’s focus on helping people maintain mental function, treating the underlying disease process, and managing behavioral symptoms.

Medications to Maintain Mental Function in Alzheimer's Disease

Several medications are approved by the U.S. Food and Drug Administration (FDA) to treat symptoms of Alzheimer’s. Donepezil, rivastigmine, and galantamine are used to treat the symptoms of mild to moderate Alzheimer’s. Donepezil, memantine, the rivastigmine patch, and a combination medication of memantine and donepezil are used to treat moderate to severe Alzheimer’s symptoms. All of these drugs work by regulating neurotransmitters, the chemicals that transmit messages between neurons. They may help reduce symptoms and help with certain behavioral problems. However, these drugs don’t change the underlying disease process. They are effective for some but not all people and may help only for a limited time.

Medications to Treat the Underlying Alzheimer's Disease Process

Aducanumab is the first disease-modifying therapy approved by the FDA to treat Alzheimer’s disease. The medication helps to reduce amyloid deposits in the brain and may help slow the progression of Alzheimer’s, although it has not yet been shown to affect clinical outcomes such as progression of cognitive decline or dementia. A doctor or specialist will likely perform tests, such as a PET scan or analysis of cerebrospinal fluid, to look for evidence of amyloid plaques and help decide if the treatment is right for the patient.

Aducanumab was approved through the FDA’s Accelerated Approval Program. This process requires an additional study after approval to confirm the anticipated clinical benefit. If the follow-up trial fails to verify clinical benefit, the FDA may withdraw approval of the drug. Results of the phase 4 clinical trial for aducanumab are expected to be available by early 2030.

Several other disease-modifying medications are being tested in people with mild cognitive impairment or early Alzheimer’s as potential treatments.

Managing Alzheimer's Disease Behavior

Common behavioral symptoms of Alzheimer’s include sleeplessness, wandering, agitation, anxiety, and aggression. Scientists are learning why these symptoms occur and are studying new treatments — drug and nondrug — to manage them. Research has shown that treating behavioral symptoms can make people with Alzheimer’s more comfortable and makes things easier for caregivers.

Support for Families and Alzheimer's Disease Caregivers

Caring for a person with Alzheimer’s can have significant physical, emotional, and financial costs. The demands of day-to-day care, changes in family roles, and decisions about placement in a care facility can be difficult. NIA supports efforts to evaluate programs, strategies, approaches, and other research to improve the quality of care and life for those living with dementia and their caregivers.

Becoming well-informed about the disease is one important long-term strategy. Programs that teach families about the various stages of Alzheimer’s and about ways to deal with difficult behaviors and other caregiving challenges can help.

Good coping skills, a strong support network, and respite care are other things that may help caregivers handle the stress of caring for a loved one with Alzheimer’s. For example, staying physically active provides physical and emotional benefits.

Some caregivers have found that joining a support group is a critical lifeline. These support groups enable caregivers to find respite, express concerns, share experiences, get tips, and receive emotional comfort. Many organizations sponsor in-person and online support groups, including groups for people with early-stage Alzheimer’s and their families.

Families have many things in common, including their genes, environment, and lifestyle. Together, these things may offer clues to diseases, like late- and early-onset Alzheimer’s, that can run in a family.

Late-Onset Alzheimer’s Disease

There is no test yet to predict if someone will get late-onset Alzheimer’s, in which symptoms become apparent in a person’s mid-60s. If someone is worried about changes in his or her memory or other problems with thinking, he or she should talk with a doctor.

A doctor may ask the patient to make a family health history. A family health history can help a person know if Alzheimer’s disease runs in the family. It lists health facts about a person and close relatives. It is a written record of:

• A family’s health conditions
• Lifestyle habits like smoking and exercise
• Where and how family members grew up

A family health history can show patterns of disease and risk factors. Try to include health facts about three generations—grandparents, parents, and children.

People can’t change the genes they inherit from their parents, but they can change things like diet, physical activity, and medical care to prevent diseases that may run in the family.

Steps to Maintain Cognitive Health

A doctor may suggest steps to stay healthy and watch for changes in memory and thinking. Steps include:

• Exercise regularly.
• Eat a healthy diet that is rich in fruits and vegetables.
• Spend time with family and friends.
• Keep one’s mind active.
• Control type 2 diabetes.
• Keep blood pressure and cholesterol at healthy levels.
• Maintain a healthy body weight.
• Stop smoking.
• Get help for depression.
• Avoid drinking a lot of alcohol.
• Get plenty of sleep.

Early-Onset Alzheimer’s Disease

There is a test to learn if a person has one of the three genetic mutations associated with early-onset Alzheimer's disease, which occurs between a person’s 30s and mid-60s.

If someone has a family history of early-onset Alzheimer's, he or she should talk with a doctor about getting tested.

A doctor may suggest meeting first with a genetic counselor. This type of counselor helps people learn the risk of getting genetic conditions. They also help people make decisions about testing and what comes next.

Many people wonder if Alzheimer’s disease runs in their family. Is it in your genes? This question isn’t easy to answer. Researchers have identified several genetic variants that are associated with Alzheimer’s and may increase or decrease a person’s risk of developing the disease. What does that mean? Let’s first learn about the role of genes.

What Are Genes?

Human cells contain the instructions needed for a cell to do its job. These instructions are made up of DNA, which is packed tightly into structures called chromosomes. Each chromosome has thousands of segments called genes.

Genes are passed down from a person’s biological parents. They carry information that defines traits such as eye color and height. Genes also play a role in keeping the body’s cells healthy.

Variations in genes — even small changes to a gene — can affect the likelihood of a person developing a disease such as Alzheimer’s.

Do Genes Cause Diseases?

Permanent changes in one or more specific genes are called genetic variants. Some of these variants are quite common in the human population. While most genetic variants don’t cause diseases, some do. In some cases, a person inherits a genetic variant that will almost certainly lead to that individual developing a disease. Sickle cell anemia, cystic fibrosis, and some cases of early-onset Alzheimer’s are examples of inherited genetic disorders. However, other variants may simply increase, or even decrease, a person’s risk of developing that disease. Identifying genetic variants and their effects can help researchers uncover the most effective ways to treat or prevent diseases in an individual.

Additionally, factors such as exercise, diet, chemicals, or smoking can have positive or negative effects by changing the way certain genes work. In the field of epigenetics, researchers are studying how such factors can alter a cell’s DNA in ways that affect gene activity.

Genetic research is a component of precision medicine, an emerging approach that considers individual variability in genes, environment, and lifestyle. Precision medicine will enable researchers and doctors to predict more accurately which treatment and prevention strategies will work in particular groups of people.

Genes and Alzheimer's Disease

In most cases, Alzheimer’s does not have a single genetic cause. Instead, it can be influenced by multiple genes in combination with lifestyle and environmental factors. Consequently, a person may carry more than one gene or group of genes that can either increase or reduce the risk of Alzheimer’s.

Importantly, people who develop Alzheimer’s do not always have a history of the disease in their families. Still, those who have a parent or sibling diagnosed with the disease have a higher risk of developing Alzheimer’s than those without that association.

Genetic variants that affect Alzheimer's disease risk

Ten years ago, researchers knew of only 10 genes linked with Alzheimer’s. Today, scientists have identified more than 70 genetic regions associated with Alzheimer’s. Understanding which genes play a role — and what role they play — may help identify new methods to prevent, delay, or treat dementia.

One well-known gene that influences Alzheimer’s risk is the apolipoprotein E (APOE) gene. The APOE gene is involved in making a protein that helps carry cholesterol and other types of fat in the bloodstream. Problems in this process are thought to contribute to the development of Alzheimer’s. APOE comes in several forms, called alleles (e.g., ε2, ε3).

• APOE ε2 may provide some protection against the disease. If Alzheimer’s occurs in a person with this allele, it usually develops later in life than it would in someone with the APOE ε4 gene. Roughly 5% to 10% of people have this allele.
• APOE ε3, the most common allele, is believed to have a neutral effect on the disease — neither decreasing nor increasing risk of Alzheimer’s.
• APOE ε4 increases risk for Alzheimer’s and is associated with an earlier age of disease onset in certain populations. About 15% to 25% of people have this allele, and 2% to 5% carry two copies.

Each person inherits two APOE alleles, one from each biological parent, meaning people can have one of six possible combinations: 2/2, 2/3, 2/4, 3/3, 3/4, and 4/4. Having two copies of APOE ε4 is associated with a higher risk of Alzheimer’s than having one copy. While inheriting APOE ε4 increases a person’s risk of Alzheimer’s, some people with an APOE ε4 allele never develop the disease.

Researchers are also finding other rare genetic variants, in addition to APOE ε2, that appear to provide some protection against developing Alzheimer’s.

However, prevalence and risk associated with APOE and other genetic variants may not be the same across all population groups. Research suggests that the degree of risk may be affected by genetic ancestry — the global geographic region from which a person is biologically descended — and differ among people of African, Asian, American Indian, and European descent. More research is needed to better understand how certain genetic variants might affect a person’s or group’s risk for Alzheimer’s and to identify treatment and prevention strategies that will work best for that particular group.

Genetic variants that cause Alzheimer's disease

Of the genetic variants so far associated with Alzheimer’s, three rare single-gene variants are known to cause the disease:

• Amyloid precursor protein (APP) on chromosome 21
• Presenilin 1 (PSEN1) on chromosome 14
• Presenilin 2 (PSEN2) on chromosome 1

A child whose biological parent carries a genetic variant for one of these three genes has a 50/50 chance of inheriting that altered version of the gene. If the variant is inherited, the child has a very strong probability of developing Alzheimer’s before age 65 and sometimes much earlier. When someone develops Alzheimer’s before age 65, it’s known as “early-onset Alzheimer’s” or sometimes “younger-onset Alzheimer’s” or “earlier-onset Alzheimer’s.” Less than 10% of all people with Alzheimer’s develop symptoms this early. Of those who do, 10% to 15% can be attributed to changes in APP, PSEN1, and PSEN2.

Changes in these three genes result in the production of abnormal proteins that are associated with the disease. Each of these mutations contributes to the breakdown of APP, a protein that’s function isn’t completely understood. The breakdown of APP is part of a process that makes harmful forms of sticky amyloid fragments. These fragments cluster to form plaques in the brain, which is a hallmark of Alzheimer’s.

In addition to the three genetic variants that are known to cause Alzheimer’s, people with Down syndrome have an extra copy of chromosome 21, which carries the APP gene, and a higher risk of developing early-onset Alzheimer’s. Estimates suggest that 50% or more of people living with Down syndrome will develop Alzheimer’s with symptoms appearing in their 50s and 60s.

Genetic testing for Alzheimer's disease

Genetic tests are not routinely used in clinical settings to diagnose or predict the risk of developing Alzheimer’s or a related dementia.

In some cases, if a person has symptoms at an early age with a strong family history of Alzheimer’s, a neurologist or other medical specialist may order a genetic test for APP, PSEN1, and PSEN2.

Although APOE testing is also available, the results cannot fully predict who will or won’t develop Alzheimer’s. Rather, this type of testing is used primarily in research settings to identify study participants who may have an increased risk of developing Alzheimer’s. This approach helps scientists look for early brain changes and compare the effectiveness of possible treatments for people with different APOE profiles.

Some people learn their APOE status through consumer genetic testing. These products are available for a fee and provide some information around the results and what they mean. While at-home genetic tests are convenient, people considering them may also benefit from talking with a doctor or genetic counselor to better understand this type of test and their test results.

Normal Function

The APP gene provides instructions for making a protein called amyloid precursor protein. This protein is found in many tissues and organs, including the brain and spinal cord (central nervous system). Little is known about the function of amyloid precursor protein. Researchers speculate that it may bind to other proteins on the surface of cells or help cells attach to one another. Studies suggest that in the brain, it helps direct the movement (migration) of nerve cells (neurons) during early development.

Amyloid precursor protein is cut by enzymes to create smaller fragments (peptides), some of which are released outside the cell. Two of these fragments are called soluble amyloid precursor protein (sAPP) and amyloid beta (β) peptide. Recent evidence suggests that sAPP has growth-promoting properties and may play a role in the formation of neurons in the brain both before and after birth. The sAPP peptide may also control the function of certain other proteins by turning off (inhibiting) their activity. Amyloid β peptide is likely involved in the ability of neurons to change and adapt over time (plasticity). Other functions of sAPP and amyloid β peptide are under investigation.

Health Conditions Related to Genetic Changes

Alzheimer's disease

Many variants (also called mutations) in the APP gene can cause early-onset Alzheimer's disease, which begins before age 65. These variants are responsible for less than 10 percent of all early-onset cases of Alzheimer's disease.

The most common APP gene variant changes one of the protein building blocks (amino acids) in the amyloid precursor protein. This variant replaces the amino acid valine with the amino acid isoleucine at protein position 717 (written as Val717Ile or V717I). Variants in the APP gene can lead to an increased amount of the amyloid β peptide or to the production of a slightly longer and stickier form of the peptide. When these protein fragments are released from the cell, they can accumulate in the brain and form clumps called amyloid plaques. These plaques are characteristic of Alzheimer's disease. A buildup of toxic amyloid β peptide and amyloid plaques may lead to the death of neurons and the progressive signs and symptoms of Alzheimer's disease.

Hereditary cerebral amyloid angiopathy

Variants in the APP gene have been found to cause hereditary cerebral amyloid angiopathy, a condition characterized by stroke and a decline in intellectual function (dementia), which begins in mid-adulthood. These variants change single amino acids in the amyloid precursor protein. Each of these variants causes a different type of the condition. The Dutch type, the most common of all the types, is caused by the replacement of the amino acid glutamic acid with the amino acid glutamine at position 22 in the protein sequence (written as Glu22Gln or E22Q). The Italian type and Arctic type are also caused by changes to glutamic acid at position 22. In the Italian type, glutamic acid is replaced with the amino acid lysine (written as Glu22Lys or E22K) and in the Arctic type, glutamic acid is replaced with the amino acid glycine (written as Glu22Gly or E22G). The Flemish type is caused by replacement of the amino acid alanine with glycine at position 21 (written as Ala21Gly or A21G). In the Iowa type, the amino acid aspartic acid is switched with the amino acid asparagine at position 23 (written as Asp23Asn or D23N). The Piedmont type of hereditary cerebral amyloid angiopathy is caused by the replacement of the amino acid leucine at position 34 with the amino acid valine (written as Leu34Val or L34V).

The result of all of these variants is the production of an amyloid β peptide that is more prone to cluster together (aggregate) than the normal peptide. The aggregated protein forms amyloid deposits that accumulate in the blood vessels of the brain. The amyloid deposits replace the muscle fibers and elastic fibers that give blood vessels flexibility, causing the blood vessels to become weak and prone to breakage. In the brain, such a break causes bleeding (hemorrhagic stroke), which can lead to brain damage and dementia or be life-threatening. Amyloid deposits in specific parts of the brain can interfere with normal brain function, leading to dementia, seizures, movement problems, and other neurological features in some people with hereditary cerebral amyloid angiopathy.

Other Names for This Gene

• A4_HUMAN
• AAA
• ABETA
• ABPP
• AD1
• amyloid beta (A4) precursor protein
• amyloid beta-peptide
• amyloid beta-protein precursor
• amyloid precursor protein
• APPI
• cerebral vascular amyloid peptide
• CVAP
• PN-II
• PN2
• protease nexin 2
• protease nexin-II

Genomic Location

Normal Function

The PSEN1 gene provides instructions for making a protein called presenilin 1. This protein is one part (subunit) of a complex called gamma- (γ-) secretase. Presenilin 1 carries out the major function of the complex, which is to cut apart (cleave) other proteins into smaller pieces called peptides. This process is called proteolysis, and presenilin 1 is described as the proteolytic subunit of γ-secretase.

The γ-secretase complex is located in the membrane that surrounds cells, where it cleaves many different proteins that span the cell membrane (transmembrane proteins). This cleavage is an important step in several chemical signaling pathways that transmit signals from outside the cell into the nucleus. One of these pathways, known as Notch signaling, is essential for the normal growth and maturation (differentiation) of hair follicle cells and other types of skin cells. Notch signaling is also involved in normal immune system function.

The γ-secretase complex may be best known for its role in processing amyloid precursor protein (APP), which is made in the brain and other tissues. γ-secretase cuts APP into smaller peptides, including soluble amyloid precursor protein (sAPP) and several versions of amyloid-beta (β) peptide. Evidence suggests that sAPP has growth-promoting properties and may play a role in the formation of nerve cells (neurons) in the brain both before and after birth. Other functions of sAPP and amyloid-β peptide are under investigation.

Health Conditions Related to Genetic Changes

Alzheimer's disease

Dozens of PSEN1 gene variants (also known as mutations) have been identified in patients with early-onset Alzheimer's disease, a degenerative brain condition that begins before age 65. Variants in the PSEN1 gene are the most common cause of early-onset Alzheimer's disease, accounting for up to 70 percent of cases.

Almost all PSEN1 gene variants change single building blocks of DNA (nucleotides) in a particular segment of the PSEN1 gene. These variants result in the production of an abnormal presenilin 1 protein. Defective presenilin 1 interferes with the function of the γ-secretase complex, which alters the processing of APP and leads to the overproduction of a longer, toxic version of amyloid-β peptide. Copies of this protein fragment stick together and build up in the brain, forming clumps called amyloid plaques that are a characteristic feature of Alzheimer's disease. A buildup of toxic amyloid-β peptide and the formation of amyloid plaques likely lead to the death of neurons and the progressive signs and symptoms of Alzheimer's disease.

Hidradenitis suppurativa

At least one variant (also known as a mutation) in the PSEN1 gene has been found to cause hidradenitis suppurativa, a chronic skin disease characterized by recurrent boil-like lumps (nodules) under the skin that develop in hair follicles. The nodules tend to become inflamed and painful, and they produce significant scarring as they heal.

The identified variant deletes a single DNA building block (nucleotide) from the PSEN1 gene, written as 725delC. This genetic change reduces the amount of functional presenilin 1 produced in cells, so less of this protein is available to act as part of the γ-secretase complex. The resulting shortage of normal γ-secretase impairs cell signaling pathways, including Notch signaling. Although little is known about the mechanism, studies suggest that abnormal Notch signaling may promote the development of recurrent nodules in hair follicles and trigger inflammation in the skin.

Studies suggest that the PSEN1 gene variant that causes hidradenitis suppurativa has a different effect on γ-secretase function than the variants that cause early-onset Alzheimer's disease. These differences may explain why no single PSEN1 gene variant has been reported to cause the signs and symptoms of both diseases.

Familial dilated cardiomyopathy

MedlinePlus Genetics provides information about Familial dilated cardiomyopathy

Other Names for This Gene

• AD3
• FAD
• presenilin 1 (Alzheimer disease 3)
• presenilin 1 protein
• PS1
• PSN1_HUMAN
• PSNL1 gene product
• S182 protein

Genomic Location

Normal Function

The PSEN2 gene provides instructions for making a protein called presenilin 2. Presenilin 2 helps process proteins that transmit chemical signals from the cell membrane into the nucleus. Once in the nucleus, these signals turn on (activate) genes that are important for cell growth and maturation.

Presenilin 2 is best known for its role in processing amyloid precursor protein, which is found in the brain and other tissues. Research suggests that presenilin 2 works together with other enzymes to cut amyloid precursor protein into smaller segments (peptides). One of these peptides is called soluble amyloid precursor protein (sAPP), and another is called amyloid beta peptide. Recent evidence suggests that sAPP has growth-promoting properties and may play a role in the formation of neurons in the brain both before and after birth. Other functions of sAPP and amyloid beta peptide are under investigation.

Health Conditions Related to Genetic Changes

Alzheimer's disease

At least 11 mutations in the PSEN2 gene have been shown to cause early-onset Alzheimer's disease. Mutations in this gene account for less than 5 percent of all early-onset cases of the disorder.

Two of the most common PSEN2 mutations that cause early-onset Alzheimer's disease change single protein building blocks (amino acids) used to make presenilin 2. One mutation replaces the amino acid asparagine with the amino acid isoleucine at position 141 (written as Asn141Ile or N141I). The other mutation changes the amino acid methionine to the amino acid valine at position 239 (written as Met239Val or M239V). These mutations appear to disrupt the processing of amyloid precursor protein, leading to the overproduction of amyloid beta peptide. This protein fragment can build up in the brain and form clumps called amyloid plaques that are characteristic of Alzheimer's disease. A buildup of toxic amyloid beta peptide and amyloid plaques may lead to the death of neurons and the progressive signs and symptoms of this disorder.

Familial dilated cardiomyopathy

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Other Names for This Gene

• AD3-like protein
• AD3L
• AD3LP
• AD4
• AD5
• Alzheimer's disease 3-like
• E5-1
• presenilin 2 (Alzheimer disease 4)
• PS2 protein (alzheimer-associated)
• PSN2_HUMAN
• PSNL2
• STM2

Genomic Location

Normal Function

The APOE gene provides instructions for making a protein called apolipoprotein E. This protein combines with fats (lipids) in the body to form molecules called lipoproteins. Lipoproteins are responsible for packaging cholesterol and other fats and carrying them through the bloodstream. Maintaining normal levels of cholesterol is essential for the prevention of disorders that affect the heart and blood vessels (cardiovascular diseases), including heart attack and stroke.

There are at least three slightly different versions (alleles) of the APOE gene. The major alleles are called e2, e3, and e4. The most common allele is e3, which is found in more than half of the general population.

Health Conditions Related to Genetic Changes

Alzheimer's disease

The e4 version of the APOE gene increases an individual's risk for developing late-onset Alzheimer's disease. Alzheimer's disease is a degenerative disease of the brain that causes dementia, which is a gradual loss of memory, judgment, and ability to function. The late-onset form of the condition occurs in people older than age 65. People who inherit one copy of the APOE e4 allele have an increased chance of developing the disease; those who inherit two copies of the allele are at even greater risk. The APOE e4 allele may also be associated with an earlier onset of memory loss and other symptoms compared to individuals with Alzheimer's disease who do not have this allele.

It is not known how the APOE e4 allele is related to the risk of Alzheimer's disease. However, researchers have found that this allele is associated with an increased number of protein clumps, called amyloid plaques, in the brain tissue of affected people. A buildup of amyloid plaques may lead to the death of nerve cells (neurons) and the progressive signs and symptoms of Alzheimer's disease.

It is important to note that people with the APOE e4 allele inherit an increased risk of developing Alzheimer's disease, not the disease itself. Not all people with Alzheimer's disease have the APOE e4 allele, and not all people who have this allele will develop the disease.

Age-related hearing loss

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Age-related macular degeneration

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Dementia with Lewy bodies

The e4 version of the APOE gene can increase the risk of developing a form of dementia called dementia with Lewy bodies; however, some people with the APOE e4 allele never develop this condition. Dementia with Lewy bodies is characterized by intellectual decline; visual hallucinations; sudden changes in attention and mood; and movement problems characteristic of Parkinson's disease such as rigidity of limbs, tremors, and impaired balance and coordination.

People who inherit one copy of the APOE e4 allele have an increased chance of developing dementia with Lewy bodies. It is unclear how the APOE e4 allele contributes to the development of this condition. It is thought that the apolipoprotein E produced from the e4 allele of the APOE gene may disrupt the transport of a protein called alpha-synuclein into and out of cells. When alpha-synuclein is trapped inside or outside of cells, it accumulates in clusters, creating Lewy bodies. Accumulation of these clusters throughout the brain impairs neuron function and ultimately causes cell death. Over time, the loss of neurons increasingly impairs intellectual and motor function and the regulation of emotions, resulting in the signs and symptoms of dementia with Lewy bodies.

It is unclear why some people with the APOE e4 allele develop Alzheimer's disease while others develop dementia with Lewy bodies.

Other disorders

Variants of apolipoprotein E have been studied extensively as risk factors for many different conditions. For example, APOE alleles have been shown to influence the risk of cardiovascular diseases. People who carry at least one copy of the APOE e4 allele have an increased chance of developing atherosclerosis, which is an accumulation of fatty deposits and scar-like tissue in the lining of the arteries. This progressive narrowing of the arteries increases the risk of heart attack and stroke.

The APOE e2 allele has been shown to greatly increase the risk of a rare condition called hyperlipoproteinemia type III. Most people with this disorder have two copies of the APOE e2 allele, leading researchers to conclude that the e2 allele plays a critical role in the development of the condition. Hyperlipoproteinemia type III is characterized by increased blood levels of cholesterol, certain fats called triglycerides, and molecules called beta-very low-density lipoproteins (beta-VLDLs), which carry cholesterol and lipoproteins in the bloodstream. A buildup of cholesterol and other fatty materials can lead to the formation of small, yellow skin growths called xanthomas and the development of atherosclerosis.

Other Names for This Gene

• Apo-E
• APOE_HUMAN
• Apolipoproteins E

Genomic Location