04:10pm Saturday 25 May 2019

Pluripotency or differentiation – that is the question

Induced pluripotent stem cells can turn into any type of cell in the body or remain in their original form. In the current edition of Molecular Cell, scientists from the Helmholtz Zentrum München describe how cells “decide” which of these two directions to take. During their research, they identified a protein and a ribonucleic acid (RNA) that play a highly significant role in this process. Their discovery also allows a better understanding of amyotrophic lateral sclerosis (ALS)*, a progressive neurological disease that affects motor neurons.

Thanks to their ability to transform into any type of cell in the body, induced pluripotent stem cells (iPS cells)** could make a key contribution to regenerative medicine. In order, for example, to generate artificial beta cells for the treatment of type 1 diabetes, it is essential to understand the mechanisms that underlie cell differentiation. Together with his team, Dr. Micha Drukker from the Institute of Stem Cell Research (ISF) at the Helmholtz Zentrum München, has now shown how such processes are controlled at the molecular level. It all began with a structure in a cell nucleus that was visualized with the aid of fluorescence microscopy.

Two key factors in the cell nucleus
“We noticed that nuclear domains named paraspeckles*** do not occur in iPS cells, but are quickly formed during the differentiation process, irrespective of the cell type that we created,” says Dr. Miha Modic, who was a member of Dr. Drukker’s working group. Drukker and Modic hypothesized that this phenomenon was linked to the ability of stem cells to differentiate into body cells. Along with Prof. Ule Jernej from University College London and Markus Grosch, a PhD student in Dr. Drukker’s group, the researchers discovered key molecules in the cell nucleus that orchestrate the appearance of paraspeckles and how they regulate differentiation.

“Two factors play key roles in the decision as to whether cells differentiate or remain pluripotent,” says Drukker. “We identified NEAT1, a ribonucleic acid (RNA), and TDP-43, a protein that binds to RNA.” NEAT1 exists in two forms. The short form is stabilized by TDP-43, and in this case, no paraspeckles develop. The cell remains pluripotent, and is not altered. Conversely, a decrease in TDP-43 creates the long form of NEAT1. Paraspeckles are formed, and an iPS cell begins to differentiate. Modic adds: “This control system may be general for stem cells to make a choice when to differentiate.” Modic further notes, “Dr Silvia Schirge and Prof. Heiko Lickert from the Institute of Diabetes and Regeneration Research (IDR) helped us to show that paraspeckles are also crucial for efficient differentiation during murine embryonic development. Together, their study provides a breakthrough in understanding processes of differentiation and development.

Link to diseases
In Drukker’s view, these findings will do more than just provide a contribution to basic research. “Paraspeckles are linked to many diseases, but up until now they have rarely been examined in the context of developmental and stem cell biology,” he explains. In the case of amyotrophic lateral sclerosis (ALS), the role of TDP-43 – as well as the appearance of paraspeckles – is particularly evident. In motor neurons, the cells that operate our muscles and are affected by ALS, TDP-43 is oddly regulated and forms toxic aggregates; and there is an increased occurrence of the long form of NEAT1, and more paraspeckles can be detected. These mechanisms are regarded as an early sign of ALS – even before patients present with clinically relevant symptoms. In the next stage, Drukker and his team of scientists hope to examine other cell types for paraspeckles, RNAs and their interactions. By then it will also be apparent whether the newly discovered molecules will provide suitable targets for pharmacotherapies.

Further information

Original publication:
Modic M et al (2019), Cross-Regulation between TDP-43 and Paraspeckles Promotes Pluripotency-Differentiation Transition. DOI: 10.1016/j.molcel.2019.03.041

Induced pluripotent stem cells (iPS cells) are stem cells that are generated in the laboratory from ordinary body cells via reprogramming. They can then turn into any type of body cell. This process is known as cellular differentiation.
2 Paraspeckles are structures in the cell nucleus that can be visualized by fluorescence microscopy. They do not always occur, but are detectable in certain cell states, for example when iPS cells differentiate into normal body cells. Paraspeckles consist of special proteins that bind ribonucleic acids (RNAs).

3 Amyotrophic lateral sclerosis (ALS)* is an incurable neurological disease that progressively affects the motors by inability to activate them. In ALS patients, certain nerve cells, the so-called motor-neurons, which are needed to control the movement of skeletal muscles, are degenerated.

As German Research Center for Environmental Health, Helmholtz Zentrum München pursues the goal of developing personalized medical approaches for the prevention and therapy of major common diseases such as diabetes mellitus, allergies and lung diseases. To achieve this, it investigates the interaction of genetics, environmental factors and lifestyle. The Helmholtz Zentrum München has about 2,300 staff members and is headquartered in Neuherberg in the north of Munich. Helmholtz Zentrum München is a member of the Helmholtz Association, a community of 19 scientific-technical and medical-biological research centers with a total of about 37,000 staff members. 
TheInstitute of Stem Cell Research (ISF) investigates the basic molecular and cellular mechanisms of stem cell maintenance and differentiation. From that, the ISF then develops approaches in order to replace defect cell types, either by activating resting stem cells or by re-programming other existing cell types to repair themselves. The aim of these approaches is to stimulate the regrowth of damaged, pathologically changed or destroyed tissue.
The research activities of the Institute of Diabetes and Regeneration Research (IDR) focus on the biological and physiological study of the pancreas and/or the insulin producing beta cells. Thus, the IDR contributes to the elucidation of the development of diabetes and the discovery of new risk genes of the disease. Experts from the fields of stem cell research and metabolic diseases work together on solutions for regenerative therapy approaches of diabetes. The IDR is part of the Helmholtz Diabetes Center (HDC).

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