Ellen Lumpkin

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Ellen Lumpkin is an American neuroscientist and professor of cell and developmental biology and neurobiology at the Helen Wills Neuroscience Institute at the University of California, Berkeley. [1] She is also co-director of the MBL Advanced Training Course in Neurobiology, and adjunct associate professor of physiology and cellular biophysics and co-director of the Thompson Family Foundation Initiative in CIPN and Sensory Neuroscience at Columbia University. [1] Lumpkin's group studies genes, cells and signals that mediate the sensation of touch. [2] Lumpkin is most interested in the somatosensory system and how it gives feedback to the brain on sensations such as pain or touch. She is known for her significant contributions in somatosensory system research. [2]

Contents

Early life and education

Lumpkin was born in rural East Texas in an agriculturally-based town, where she spent her childhood years driving tractors and raising cows and pigs. In high school, she joined Future Farmers of America, which fully funded her college education given that she majored in agriculture and went to a local state university. Lumpkin earned a B.S. in Animal Science at Texas Tech University in Lubbock, Texas. [1] During her undergraduate years, Lumpkin studied the effects of stress on the health of animals, more specifically, how certain social or shipping conditions can lead to weight loss of pigs by the stress hormone cortisol. Lumpkin performed PhD training in neuroscience with A. James Hudspeth at University of Texas Southwestern and the Rockefeller University. [1]

Merkel Cell Blausen 0805 Skin MerkelCell.png
Merkel Cell

Career and research

Lumpkin worked at Columbia University as an associate professor and researcher for 11 years. [2] She now does research at the University of California, Berkeley in the Molecular and Cell Biology department studying the somatosensory system. [2] [3] Lumpkin's lab studies the somatosensory pathways that encode various stimuli like touch, vibration, and texture. [4] Her research is on the skin's sensory neurons pick up tactile features of objects and how skin cells communicate with the neuro system to encode touch. [5]

Merkel cells are found in clusters called touch domes, which are then connected to neuronal networks. [2] Lumpkin studies how these cells respond to the sensation of touch by sensing shape, form, and texture. [6] Ellen Lumpkin and her team discovered the specialization of Merkel cells involved in encoding different aspects of the sensation of touch. [1] [7] Her team discovered that Merkel cells have fast, mechanically activated ion channels, they are capable of sending information to activate sensory neurons, and the activity of Merkel cells is required during touch stimulation. [1] These findings allowed her lab to conclude that Merkel cells are mechanosensory receptor cells, and she published a paper explaining these results in 2019. [8] Her research has also disproved the common belief that Merkel cells are descended from the neural crest, instead showing that they originate in the skin [9]

Awards

On January 15, 1999, she received the Runyon-Winchell Fellowship Award. [10] She won the Schaefer Scholars Award in 2015. She currently serves as the Co-Director of the Thompson Family Foundation Initiative in CIPN & Sensory Neuroscience. [11]

Related Research Articles

In physiology, nociception, also nocioception; from Latin nocere 'to harm/hurt') is the sensory nervous system's process of encoding noxious stimuli. It deals with a series of events and processes required for an organism to receive a painful stimulus, convert it to a molecular signal, and recognize and characterize the signal to trigger an appropriate defensive response.

<span class="mw-page-title-main">Sensory nervous system</span> Part of the nervous system

The sensory nervous system is a part of the nervous system responsible for processing sensory information. A sensory system consists of sensory neurons, neural pathways, and parts of the brain involved in sensory perception and interoception. Commonly recognized sensory systems are those for vision, hearing, touch, taste, smell, balance and visceral sensation. Sense organs are transducers that convert data from the outer physical world to the realm of the mind where people interpret the information, creating their perception of the world around them.

<span class="mw-page-title-main">Parietal lobe</span> Part of the brain responsible for sensory input and some language processing

The parietal lobe is one of the four major lobes of the cerebral cortex in the brain of mammals. The parietal lobe is positioned above the temporal lobe and behind the frontal lobe and central sulcus.

Stimulus modality, also called sensory modality, is one aspect of a stimulus or what is perceived after a stimulus. For example, the temperature modality is registered after heat or cold stimulate a receptor. Some sensory modalities include: light, sound, temperature, taste, pressure, and smell. The type and location of the sensory receptor activated by the stimulus plays the primary role in coding the sensation. All sensory modalities work together to heighten stimuli sensation when necessary.

A mechanoreceptor, also called mechanoceptor, is a sensory receptor that responds to mechanical pressure or distortion. Mechanoreceptors are innervated by sensory neurons that convert mechanical pressure into electrical signals that, in animals, are sent to the central nervous system.

<span class="mw-page-title-main">Sensory neuron</span> Nerve cell that converts environmental stimuli into corresponding internal stimuli

Sensory neurons, also known as afferent neurons, are neurons in the nervous system, that convert a specific type of stimulus, via their receptors, into action potentials or graded receptor potentials. This process is called sensory transduction. The cell bodies of the sensory neurons are located in the dorsal root ganglia of the spinal cord.

<span class="mw-page-title-main">Star-nosed mole</span> Species of Mole

The star-nosed mole is a small semiaquatic mole found in moist, low elevation areas in the northern parts of North America. It is the only extant member of the tribe Condylurini and genus Condylura, and it has more than 25,000 minute sensory receptors in touch organs, known as Eimer's organs, with which this hamster-sized mole feels its way around. With the help of its Eimer's organs, it may be perfectly poised to detect seismic wave vibrations.

<span class="mw-page-title-main">Merkel cell</span> Receptors in the skin of vertebrates

Merkel cells, also known as Merkel–Ranvier cells or tactile epithelial cells, are oval-shaped mechanoreceptors essential for light touch sensation and found in the skin of vertebrates. They are abundant in highly sensitive skin like that of the fingertips in humans, and make synaptic contacts with somatosensory afferent nerve fibers. It has been reported that Merkel cells are derived from neural crest cells, though more recent experiments in mammals have indicated that they are epithelial in origin.

<span class="mw-page-title-main">Lateral inhibition</span> Capacity of an excited neuron to reduce activity of its neighbors

In neurobiology, lateral inhibition is the capacity of an excited neuron to reduce the activity of its neighbors. Lateral inhibition disables the spreading of action potentials from excited neurons to neighboring neurons in the lateral direction. This creates a contrast in stimulation that allows increased sensory perception. It is also referred to as lateral antagonism and occurs primarily in visual processes, but also in tactile, auditory, and even olfactory processing. Cells that utilize lateral inhibition appear primarily in the cerebral cortex and thalamus and make up lateral inhibitory networks (LINs). Artificial lateral inhibition has been incorporated into artificial sensory systems, such as vision chips, hearing systems, and optical mice. An often under-appreciated point is that although lateral inhibition is visualised in a spatial sense, it is also thought to exist in what is known as "lateral inhibition across abstract dimensions." This refers to lateral inhibition between neurons that are not adjacent in a spatial sense, but in terms of modality of stimulus. This phenomenon is thought to aid in colour discrimination.

Group Aβ of the type II sensory fiber is a type of sensory fiber, the second of the two main groups of touch receptors. The responses of different type Aβ fibers to these stimuli can be subdivided based on their adaptation properties, traditionally into rapidly adapting (RA) or slowly adapting (SA) neurons. Type II sensory fibers are slowly-adapting (SA), meaning that even when there is no change in touch, they keep respond to stimuli and fire action potentials. In the body, Type II sensory fibers belong to pseudounipolar neurons. The most notable example are neurons with Merkel cell-neurite complexes on their dendrites and Ruffini endings. Under pathological conditions they may become hyper-excitable leading to stimuli that would usually elicit sensations of tactile touch causing pain. These changes are in part induced by PGE2 which is produced by COX1, and type II fibers with free nerve endings are likely to be the subdivision of fibers that carry out this function.

Tactile discrimination is the ability to differentiate information through the sense of touch. The somatosensory system is the nervous system pathway that is responsible for this essential survival ability used in adaptation. There are various types of tactile discrimination. One of the most well known and most researched is two-point discrimination, the ability to differentiate between two different tactile stimuli which are relatively close together. Other types of discrimination like graphesthesia and spatial discrimination also exist but are not as extensively researched. Tactile discrimination is something that can be stronger or weaker in different people and two major conditions, chronic pain and blindness, can affect it greatly. Blindness increases tactile discrimination abilities which is extremely helpful for tasks like reading braille. In contrast, chronic pain conditions, like arthritis, decrease a person's tactile discrimination. One other major application of tactile discrimination is in new prosthetics and robotics which attempt to mimic the abilities of the human hand. In this case tactile sensors function similarly to mechanoreceptors in a human hand to differentiate tactile stimuli.

Mechanosensation is the transduction of mechanical stimuli into neural signals. Mechanosensation provides the basis for the senses of light touch, hearing, proprioception, and pain. Mechanoreceptors found in the skin, called cutaneous mechanoreceptors, are responsible for the sense of touch. Tiny cells in the inner ear, called hair cells, are responsible for hearing and balance. States of neuropathic pain, such as hyperalgesia and allodynia, are also directly related to mechanosensation. A wide array of elements are involved in the process of mechanosensation, many of which are still not fully understood.

<span class="mw-page-title-main">Somatosensory system</span> Nerve system for sensing touch, temperature, body position, and pain

The somatosensory system, or somatic sensory system is a subset of the sensory nervous system. It has two subdivisions, one for the detection of mechanosensory information related to touch, and the other for the nociception detection of pain and temperature. The main functions of the somatosensory system are the perception of external stimuli, the perception of internal stimuli, and the regulation of body position and balance (proprioception).

A sense is a biological system used by an organism for sensation, the process of gathering information about the surroundings through the detection of stimuli. Although, in some cultures, five human senses were traditionally identified as such, many more are now recognized. Senses used by non-human organisms are even greater in variety and number. During sensation, sense organs collect various stimuli for transduction, meaning transformation into a form that can be understood by the brain. Sensation and perception are fundamental to nearly every aspect of an organism's cognition, behavior and thought.

Rishikesh Narayanan is an Indian neuroscientist, computer engineer and a professor at the Molecular Biophysics Unit (MBU) of the Indian Institute of Science. He is the principal investigator at the Cellular Neurophysiology Laboratory of MBU where his team is engaged in researches on experimental and theoretical aspects of information processing in single neurons and their networks. The Council of Scientific and Industrial Research, the apex agency of the Government of India for scientific research, awarded him the Shanti Swarup Bhatnagar Prize for Science and Technology, one of the highest Indian science awards, in 2016, for his contributions to biological sciences.

<span class="mw-page-title-main">Elba Serrano</span> Professor of Neuroscience

Elba E. Serrano is a neuroscientist and biophysicist who holds a position as a Regent's Professor of Biology at New Mexico State University.

Lauren Orefice is an American neuroscientist and assistant professor in the Department of Molecular Biology at Massachusetts General Hospital and in the Department of Genetics at Harvard Medical School. Orefice has made innovative discoveries about the role of peripheral nerves and sensory hypersensitivity in the development of Autism-like behaviors. Her research now focuses on exploring the basic biology of somatosensory neural circuits for both touch and gastrointestinal function in order to shed light on how peripheral sensation impacts brain development and susceptibility to diseases like Autism Spectrum Disorders.

Theanne Griffith is an American neuroscientist and children's book author. She is an assistant professor of Physiology and Membrane Biology at the University of California, Davis.

Valeria Gazzola is an Italian neuroscientist, associate professor at the Faculty of Social and Behavioral Sciences at the University of Amsterdam (UvA) and member of the Young Academy of Europe. She is also a tenured department head at the Netherlands Institute for Neuroscience (NIN) in Amsterdam, where she leads her own research group and the Social Brain Lab together with neuroscientist Christian Keysers. She is a specialist in the neural basis of empathy and embodied cognition: Her research focusses on how the brain makes individuals sensitive to the actions and emotions of others and how this affects decision-making.

Sliman Julien Bensmaia was a French-Algerian neuroscientist. An international expert in the neural encoding of sensory information and a pioneer in robotic neuroprosthetics, his nearly 100 academic articles in somatosensation have been cited over 10,000 times. He is the principal architect of the biomimetic approach to naturalistic restoration of the sensations of touch and proprioception in amputees and paralyzed patients.

References

  1. 1 2 3 4 5 6 "Meet-the-Expert: Feeling the Pressure – My Path to Sensory Neuroscience with Ellen A. Lumpkin, PhD". neuronline.sfn.org. Retrieved 2021-12-06.
  2. 1 2 3 4 5 "Episode 16: Ellen Lumpkin, PhD". Conjugate: Illustration and Science Blog. Retrieved 2021-12-01.
  3. "Ellen Lumpkin". The Daily Sentinel. Retrieved 2021-12-06.
  4. Wellnitz, Scott A.; Lesniak, Daine R.; Gerling, Gregory J.; Lumpkin, Ellen A. (2010). "The Regularity of Sustained Firing Reveals Two Populations of Slowly Adapting Touch Receptors in Mouse Hairy Skin". Journal of Neurophysiology. 103 (6): 3378–3388. doi:10.1152/jn.00810.2009. ISSN   0022-3077. PMC   2888253 . PMID   20393068.
  5. "The Pipette Gazette » Uncovering Our Sense of Touch: Dr. Ellen Lumpkin". pipettegazette.uthscsa.edu. Retrieved 2021-12-06.
  6. Lumpkin, Ellen A.; Caterina, Michael J. (2007). "Mechanisms of sensory transduction in the skin". Nature. 445 (7130): 858–865. Bibcode:2007Natur.445..858L. doi:10.1038/nature05662. ISSN   1476-4687. PMID   17314972. S2CID   4391105.
  7. "PBIO seminar series: Ellen Lumpkin". Physiology and Biophysics. Retrieved 2021-12-06.
  8. Jenkins, Blair A; Fontecilla, Natalia M; Lu, Catherine P; Fuchs, Elaine; Lumpkin, Ellen A (2019-02-22). Nathans, Jeremy; Bronner, Marianne E (eds.). "The cellular basis of mechanosensory Merkel-cell innervation during development". eLife. 8: e42633. doi: 10.7554/eLife.42633 . ISSN   2050-084X. PMC   6386521 . PMID   30794158.
  9. Morrison, Kristin M.; Miesegaes, George R.; Lumpkin, Ellen A.; Maricich, Stephen M. (2009-12-01). "Mammalian Merkel cells are descended from the epidermal lineage". Developmental Biology. 336 (1): 76–83. doi:10.1016/j.ydbio.2009.09.032. ISSN   0012-1606. PMC   2783667 . PMID   19782676.
  10. "Online News Vol. 3, No. 2: Jan. 15, 1999". depts.washington.edu. Retrieved 2021-12-01.
  11. "The Science Behind a Soft Caress". Columbia University Irving Medical Center. 2018-11-08. Retrieved 2021-12-06.
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