Current risk genes for some diseases such as multiple sclerosis (MS) may have emerged in the past as protection against infection by different pathogens. A group of researchers led by scientists from the University of Copenhagen has analyzed the ancient DNA of European populations and has revealed how MS, Alzheimer’s disease (AD) and diabetes arose as populations migrated. This evolution would explain the modern genetic diversity and the incidences of these pathologies observed today in the old continent.

Listening to conversations between a mother and her unborn child on the cellular level could inform how the pregnancy is going and prevent complications. Three scientific groups from the Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD), in collaboration with Wayne State University and Michigan State University, have used single-cell RNA sequencing techniques to decipher these words, identify the cellular language of these interactions in the placenta and establish a cellular atlas.

Current risk genes for some diseases such as multiple sclerosis (MS) may have emerged in the past as protection against infection by different pathogens. A group of researchers led by scientists from the University of Copenhagen has analyzed the ancient DNA of European populations and has revealed how MS, Alzheimer’s disease (AD) and diabetes arose as populations migrated. This evolution would explain the modern genetic diversity and the incidences of these pathologies observed today in the old continent.

If we unraveled the DNA of the 46 chromosomes of a single human cell, it would barely measure 2 meters. If we did the same with the rest of the body, if we aligned the 3 billion base pairs of its 5 trillion cells, we could travel the distance from the Earth to the Sun more than 100 times. It seems unreachable. However, that is the unit of knowledge of the large sequencing projects achieved in 2023.

If we unraveled the DNA of the 46 chromosomes of a single human cell, it would barely measure 2 meters. If we did the same with the rest of the body, if we aligned the 3 billion base pairs of its 5 trillion cells, we could travel the distance from the Earth to the Sun more than 100 times. It seems unreachable. However, that is the unit of knowledge of the large sequencing projects achieved in 2023. From the generation of the human pangenome to cell-by-cell maps of the brain and kidneys, scientists this year have completed several omics collaborative projects stored in large international databases. Now, what’s the plan?

Modifying a patient’s DNA is no longer just for science fiction novels. The CRISPR gene editing technique developed by Jennifer Doudna and Emmanuelle Charpentier only took 10 years to reach the market as Casgevy (exagamglogene autotemcel/exa-cel, Vertex Pharmaceuticals Inc.), treating congenital pathologies such as β-thalassemia and severe sickle cell disease. But science does not stop.

If we unraveled the DNA of the 46 chromosomes of a single human cell, it would barely measure 2 meters. If we did the same with the rest of the body, if we aligned the 3 billion base pairs of its 5 trillion cells, we could travel the distance from the Earth to the Sun more than 100 times. It seems unreachable. However, that is the unit of knowledge of the large sequencing projects achieved in 2023. From the generation of the human pangenome to cell-by-cell maps of the brain and kidneys, scientists this year have completed several omics collaborative projects stored in large international databases. Now, what’s the plan?

Modifying a patient’s DNA is no longer just for science fiction novels. The CRISPR gene editing technique developed by Jennifer Doudna and Emmanuelle Charpentier only took 10 years to reach the market as Casgevy (exagamglogene autotemcel/exa-cel, Vertex Pharmaceuticals Inc.), treating congenital pathologies such as β-thalassemia and severe sickle cell disease (SCD). But science does not stop.

Scientists at Regeneron Pharmaceuticals Inc. have found a new way to permanently stop allergy through a combination of therapies that prevents the production of antibodies in secondary lymphoid organs and in bone marrow. The approach was tested in vivo in cynomolgus monkeys and in a mouse model.

Although there are different methods of nuclear gene editing, there are still no effective treatments against mitochondrial disorders due to genetic alterations. Now, a group of researchers at Precision Biosciences Inc. and the University of Miami (UM) has developed a genetic edition platform that targets mitochondrial DNA (mtDNA) to delete its mutations.

“The ARCUS technology that we use is based on an enzyme found in nature called I-CreI. It is an enzyme that recognizes a 22 base pair DNA sequence within a species of green algae. And when it finds that DNA sequence, it will generate double-strand breaks,” first author Wendy Shoop, a scientist at Precision Biosciences, told BioWorld.