or technically,

Adolescent Chronic Unpredictable Stress Exposure Is a Sensitive Window for Long-Term Changes in Adult Behavior in Mice.

[See Original Abstract on Pubmed]

Authors of the study: Nicole L Yohn & Julie A Blendy

or technically,

Glucagon-like peptide-1 receptor activation in the ventral tegmental area attenuates cocaine seeking in rats.

[See Original Abstract on Pubmed]

Authors of the study: Nicole S. Hernandez, Kelsey Y. Ige, Elizabeth G. Mietlicki-Baase, Gian Carlo Molina-Castro, Christopher A. Turner, Matthew R. Hayes, & Heath D. Schmidt

Citations:

1. Warner M, Trinidad JP, Bastian BA, et al. Drugs most frequently involved in drug overdose deaths: United States, 2010–2014. National vital statistics reports; vol 65 no 10. Hyattsville, MD: National Center for Health Statistics. 2016.

2. Schmidt HD, Mietlicki-Baase EG, Ige KY, Maurer JJ, Reiner DJ, Zimmer DJ, et al. Glucagon-like peptide-1 receptor activation in the ventral tegmental area decreases the reinforcing efficacy of cocaine. Neuropsychopharmacology. 2016;41:1917–1928.

Formatted link to the paper goes here.

or technically,

Signals in inferotemporal and perirhinal cortex suggest an untangling of visual target information.

[See Original Abstract on Pubmed]

Authors of the study: Marino Pagan, Luke S Urban, Margot P Wohl, Nicole C Rust

Citations:

1. https://medium.com/deep-dimension/an-analysis-on-computer-vision-problems-6c68d56030c3

2. Chelazzi, L., & Desimone, R. (1993). A neural basis for visual search in IT. Nature. 363, pages 345–347.

3. Meunier, M., Bachevalier, J., Mishkin, M. & Murray, E.A. Effects on visual recognition of combined and separate ablations of the entorhinal and perirhinal cortex in rhesus monkeys. J. Neurosci. 13, 5418–5432 (1993).

To learn more about how the brain helps us quickly identify what we’re looking for, check out the full paper here.

or technically,

Sparse genetic tracing reveals regionally specific functional organization of mammalian nociceptors.

[See Original Abstract on Pubmed]

Authors of the study: William Olson, Ishmail Abdus-Saboor, Lian Cui, Justin Burdge, Tobias Raabe, Minghong Ma, Wenqin Luo

Do you want to learn more about how we feel pain? You can read Will’s entire paper here.

or technically,

Exploring the relationship between cortical GABA concentrations, auditory gamma-band responses and development in ASD: Evidence for an altered maturational trajectory in ASD.

[See Original Abstract on Pubmed]

Authors of the study: Russell G. Port, William Gaetz, Luke Bloy, Dah-Jyuu Wang, Lisa Blaskey, Emily S. Kuschner, Susan E. Levy, Edward S. Brodkin, and Timothy P.L. Roberts

Citations:

1. Autism and Developmental Disabilities Monitoring Network Surveillance Year 2010 Principal Investigators. “Prevalence of Autism Spectrum Disorder Among Children Aged 8 Years — Autism and Developmental Disabilities Monitoring Network, 11 Sites, United States, 2010.” Morbidity and Mortality Weekly Report: Surveillance Summaries, vol. 63, no. 2, 2014, pp. 1–21. 

2. Stephen J. Blumberg, Matthew D. Bramlett, Michael D. Kogan, Laura A. Schieve, Jessica R. Jones, Michael C. Lu. “Changes in Prevalence of Parent-Reported Autism Spectrum Disorder in School-Aged U.S. Children: 2007 to 2011-2012. National Center for Health Statistics Reports.” National Center for Health Statistics, number 65, 2013.

Do you want to learn more about ASD and development? You can read Russ’s whole paper here.

or technically,

Differential α‑synuclein expression contributes to selective vulnerability of hippocampal neuron subpopulations to fibril‑induced toxicity.

[See Original Abstract on Pubmed]

Authors of the study: Esteban Luna, Samantha C. Decker, Dawn M. Riddle, Anna Caputo, Bin Zhang, Tracy Cole, Carrie Caswell, Sharon X. Xie, Virginia M. Y. Lee, Kelvin C. Luk

or technically,

Social Coordination in Older Adulthood: A Dual-Process Model.

[See Original Abstract on Pubmed]

Authors of the study: Meghan L. Healey and Murray Grossman

Citations:

1. Ganster, D. C., & Victor, B. (1988). The impact of social support on mental and physical health. British Journal of Medical Psychology, 61(1), 17-36.

If you are interested in learning more about how aging changes the way we interact with one another, check out Meghan’s paper here.

or technically,

Loss of the neurodevelopmental gene Zswim6 alters striatal morphology and motor regulation.

[See Original Abstract on Pubmed]

Authors of the study: David J. Tischfield, Dave K. Saraswat, Andrew Furash, Stephen C. Fowler, Marc V. Fuccillo, Stewart A. Anderson

Citations:

1. Ripke, S., et al., 2013. Genome-wide association analysis identifies 13 new risk loci for schizophrenia. Nat. Genet. 45:1150–1159. Read it here. 

2. Schizophrenia Working Group of the Psychiatric Genomics, C, 2014,. Biological insights from 108 schizophrenia-associated genetic loci. Nature 511:421–427. Read it here.

Want to learn more about how researchers study neurodevelopmental disorders like schizophrenia? You can find David’s full paper here!

or technically,

Distinct cellular and molecular environments support aging-related DNA methylation changes in the substantia nigra.

[See Original Abstract on Pubmed]

Authors of the study: Maria Fasolino, Shuo Liu, Yinsheng Wang and Zhaolan Zhou

Interested in learning more about the epigenetics of aging? Take a look at Maria’s full paper here!

or technically,

Amylin acts in the lateral dorsal tegmental nucleus to regulate energy balance Through GABA Signaling.

[See Original Abstract on Pubmed]

Authors of the study: David J. Reiner, Elizabeth G. Mietlicki-Baase, Diana R. Olivos, Lauren E. McGrath, Derek J. Zimmer, Kieran Koch-Laskowski, Joanna Krawczyk, Christopher A. Turner, Emily E. Noble, Joel D. Hahn, Heath D. Schmidt, Scott E. Kanoski, Matthew R. Hayes

or technically,

Endocytosis at the Drosophila blood-brain barrier as a function for sleep.

[See Original Abstract on Pubmed]

Authors of the study: Gregory Artiushin, Shirley L Zhang, Hervé Tricoire, Amita Sehgal

Citations:

1. Shokri-Kojori E, Wang G, Wier CE, Demiral SB, Guo M, Kim SW . . . Volkow ND. (2018). β-Amyloid accumulation in the human brain after one night of sleep deprivation. Proceedings of the National Academy of Sciences, 115(17): 4483-4488. You can find the paper here.

2. Halassa MM, Florian C, Fellin T, Munoz JR, Lee S, Abel T . . . Frank MG. (2009). Astrocytic modulation of sleep homeostasis and cognitive consequences of sleep loss. Neuron, 61(2): 213-219. You can find the paper here.

3. Pandey UB & Nichols CD. (2001). Human disease models in Drosophila melanogaster and the role of the fly in therapeutic drug discovery. Pharmacological Reviews, 11(6): 1114-1125. You can find the paper here.

or technically,

Age-Related Effects and Sex Differences in Gray Matter Density, Volume, Mass, and Cortical Thickness from Childhood to Young Adulthood

[See Original Abstract on Pubmed]

Authors of the study: Gennatas ED, Avants BB, Wolf DH, Satterthwaite TD, Ruparel K, Ciric R, Hakonarson H, Gur RE, Gur RC.

Citations:

1. Akshoomoff, N., Newman, E., Thompson, W. K., McCabe, C., Bloss, C. S., Chang, L., ... & Gruen, J. R. (2014). The NIH Toolbox Cognition Battery: Results from a large normative developmental sample (PING). Neuropsychology, 28(1), 1.

or technically,

Roof Plate-Derived Radial Glial-like Cells Support Developmental Growth of Rapidly Adapting Mechanoreceptor Ascending Axons

[See Original Abstract on Pubmed]

Authors of the study: Kim Kridsada, Jingwen Niu, Zhiping Wang,Parthiv Haldipur, Long Ding, Jian J. Li, Anne G. Lindgren, Eloisa Herrera, Gareth M. Thomas, Victor V. Chizhikov, Kathleen J. Millen, and Wenqin Luo

Do you want to learn more about touch, RGLCs, and development? You can read Kim’s whole paper here.

or, technically,
Characterizing the impact of category uncertainty on human auditory categorization behavior.[See the original abstract on PubMed]

Authors: Adam M. Gifford, Yale E. Cohen, Alan A. Stocker

Brief prepared by: Adam Gifford & Kate Christison-Lagay
Brief approved by: Peter Dong
Section Chief: Yunshu Fan
Date posted: May 3, 2016

Brief in Brief (TL;DR)

What do we know: We can group and split up sounds (and other things) into different categories, which allows us to identify and understand what is in the environment. However, choosing the best category for a sound can be difficult because sounds can belong to more than one category. For example, both dogs and wolves can howl, and incorrectly categorizing a wolf’s howl as a dog’s can be dangerous. 

What don’t we know: How we use past experience with similar sounds to categorize new, unfamiliar sounds. 

What this study shows: We use previous experience with similar sounds to make a best guess on how to categorize new sounds. Our brain isn’t perfect, though—it has a lot of activity that isn’t related to what we’re experiencing (this is called noise), so our performance isn’t perfect. But it is as good as it can be given the noise in the brain. 

What we can do in the future because of this study: Record from neurons in different parts of the brain to determine where experience with previous sounds and their categories are stored, and how and where the brain uses that information to choose a category for new sounds. 

Why you should care: Understanding how humans use prior experience to categorize new information will allow us to determine what goes wrong when we make categorization errors. This understanding could also be used to develop tools that can allow computers to perform the same kinds of categorizations, which would be useful for automated object or voice recognition.

Brief for Non-Neuroscientists

The ability to group and segregate sounds (or objects) into different categories is an important process that allows us to simplify and understand the environment. However, determining the best category for a sound can be difficult, as some sounds can belong to multiple categories. For example, both dogs and wolves can howl, and incorrectly categorizing a wolf’s howl as a dog’s can be dangerous. To solve this problem, the brain must use information learned from experience in categorizing similar sounds in the past. We expected that humans would use previous experience to decide on the best category for a new sound, minimizing the chance that they chose wrong. However, we found that humans did not seem to use the best decision strategy that minimized categorization errors. But if we assume that there is noise in the brain that limits the ability to accurately keep track of previous experience, humans’ category choices can be consistent with the best decision strategy.

Brief for Neuroscientists

Categorization is an important process that allows us to simplify, extract meaning from, and respond to sounds (or other objects) in the environment. However, categorization is complicated because a sound can belong to multiple categories. Thus, to choose the best category for a new sound, we must make use of prior information on the categories of similar sounds. Given the importance of categorization, we hypothesized that humans utilize the best decision strategy for making categorical judgments that allows us to minimize categorization errors. However, we found that humans did not minimize errors in their categorization behavior, similar to behaviors exhibited in other perceptual and cognitive tasks. We then explored the bases for this sub-optimal behavior and found that it can be consistent with the best strategy if we assume that humans have trial-by-trial noise in components of the judgment process.

or, technically, 
Optineurin is an autophagy receptor for damaged mitochondria in parkin-mediated mitophagy that is disrupted by an ALS-linked mutation [See the original abstract on PubMed]

Authors: Yvette C. Wong, Erika L.F. Holzbaur

Brief prepared by: Shachee Doshi and Patti Murphy
Brief approved by: Peter Dong
Section Chief: Shachee Doshi
Date posted: March 8, 2017 

Brief in Brief (TL;DR)

What do we know: Mitochondria are machines in our cells that produce energy. When mitochondria get damaged, healthy cells break down the damaged mitochondria and throw them away. In neurodegenerative diseases like ALS (Lou Gehrig's disease), damaged mitochondria inside neurons are not broken down, and this might be one way in which neurons die. 

What don’t we know: Why are damaged mitochondria not broken down inside neurons in people with neurodegenerative diseases? Can we find ways to help these people's neurons break down damaged mitochondria? 

What this study shows: A protein called optineurin helps cells break down damaged mitochondria. When there isn't enough optineurin or the optineurin is abnormal (like it is in some cases of ALS), damaged mitochondria are no longer broken down and build up in the neuron. 

What we can do in the future because of this study: We could design drugs to make optineurin even better at breaking down damaged mitochondria. These drugs would first be tested to see if they help animals with neurodegenerative diseases and then if they help humans with these diseases. 

Why you should care: Neurodegenerative diseases (Alzheimer's Disease, ALS, Frontotemporal Dementia) cause a lot of pain to patients and their families and cost a lot of money to society as a whole. Damaged mitochondria are found in neurons of patients in all these diseases. Finding ways to help cells break down damaged mitochondria can help us treat patients with these diseases.

Brief for Non-Neuroscientists

Mitochondria are the energy powerhouses of the cell. They make the fuel for all the cellular machinery to run smoothly. Accumulation of damaged and dysfunctional mitochondria has been observed in many neurodegenerative diseases, including ALS, Alzheimer's disease and Parkinson's disease. 

While it is unknown how mitochondria become damaged, it is known that accumulation of malfunctioning mitochondria is one of the factors contributing to neuronal cell death. Normally, a cell discards its damaged parts by a process known as autophagy. When it is mitochondria that are being discarded, this process is called mitophagy. 

One reason damaged mitochondria might build up in neurodegenerative diseases is defective mitophagy. If there were a way to rescue this defect, it could help cells get rid of these damaged mitochondria. This study identifies a pathway to do just that. The authors find that a protein called optineurin can be recruited to the mitochondria, which in turn leads to the recruitment of autophagosomes. Autophagosomes are special structures that envelop and engulf damaged cellular material to degrade it. If optineurin is removed from the cell, autophagosomes are no longer recruited to damaged mitochondria. Adding normal optineurin back into the cell can rescue autophagosome recruitment, but adding back an altered (mutated) form of optineurin that is found in ALS cannot rescue autophagosome recruitment. 

This study tells us that it may be possible to treat neurodegenerative diseases by increasing the amount of normal optineurin available in cells.

Brief for Neuroscientists

Mitochondrial dysfunction is a hallmark of many neurodegenerative diseases including ALS, frontotemporal dementia and Alzheimer's disease, and is implicated in disease pathophysiology. While mitophagy is a well-understood quality control mechanism that can degrade dysfunctional mitochondria, it seems to be compromised in these diseases. Optineurin is a protein that binds ubiquitin and the autophagosome via its LC3-binding domain, thus acting as an autophagy receptor. Mutations in optineurin have been found in familial cases of ALS. This paper describes a parkin-dependent role for optineurin in mitophagy in vitro. Using HeLa cells and confocal microscopy, the authors find that parkin is required to stabilize optineurin on the mitochondrial membrane, which in turn recruits the protein LC3 to initialize autophagosome formation. Depleting optineurin prevents autophagosome recruitment and mitochondrial turnover. This can be rescued by expressing wild type optineurin but not an ALS-linked mutant optineurin. Further, deleting autophagy receptor p62 did not prevent autophagosome formation, indicating a specific role for optineurin in initiating mitophagy. This study presents evidence for the contribution of mitochondrial dysfunction to cell death in neurodegeneration, and describes a mechanistic role for optineurin in mitophagy.

or, technically, 
Lysosomal alkalization and dysfunction in human fibroblasts with the Alzheimer’s disease-linked presenilin 1 A246E mutation can be reversed with cAMP [See the original abstract on PubMed]

Authors: Erin E. Coffey, Jonathan M. Beckel, Alan M. Laties, Claire H. Mitchell

Brief prepared by: Alice Dallstream
Brief approved by: Ari Kahn
Section Chief: Alyse Thomas
Date posted: June 8, 2016 

Brief in Brief (TL;DR)

What do we know: Alzheimer’s disease is the leading cause of dementia and can be inherited through changes in a gene called PS1. These changes makes it hard for neurons and other cells to get rid of their waste, and make the cells less healthy. 

What don’t we know: We don’t know how these changes in the PS1 gene impairs waste recycling in cells. 

What this study shows: In cells from patients who have changes in PS1, the part of the cell responsible for recycling is not as acidic as normal recycling centers, making them less effective. If you make these recycling cell parts more acidic in PS1 cells, they regain their function. 

What we can do in the future because of this study: We have more information on what is going wrong in the messed up PS1 neurons and can use this information to develop therapy for Alzheimer’s patients. 

Why you should care: Alzheimer’s disease currently has no cure and is increasingly common among the elderly. By figuring out what goes wrong in the cells of Alzheimer’s patients, we can find potential ways to treat it.

Brief for Non-Neuroscientists

There is a mutation in a gene called presenilin 1 (PS1) that is one of the leading causes of familial Alzheimer’s disease. This mutation in PS1 makes it hard for cells to clear their waste and recycle these molecules to stay healthy. The major “waste facility” of the cell is an organelle called the lysosome. When the lysosome becomes less acidic than normal, it struggles to clear and recycle the waste building up in the cell. This study explored whether there is a change in acidity in the lysosome in cells with the PS1 mutation. Using a new and very sensitive technique to measure acidity changes in the lysosomes of the skin cells in patients with the PS1 mutation and in healthy controls, the researchers were able to see that the PS1 lysosomes were less acidic than healthy lysosomes. This reduction in acidity was shown to impair the lysosome’s ability to recycle and breakdown waste products. The scientists then used a molecule called cAMP to restore the typical acidity in the PS1 lysosomes, and this helped to improve the function of the lysosomes in taking care of the waste products. The researchers suggest that this might be a new way of treating Alzheimer’s disease in patients with the PS1 mutation.

Brief for Neuroscientists

Impairments in autophagy in neurons is characteristic of many neurodegenerative diseases, including Alzheimer’s disease. A transmembrane protein in the lysosome called presenilin 1 (PS1) is one of the most common mutations in early-onset Alzheimer’s. The mutation in PS1 creates autophagy pathology and leads to buildup of amyloid beta, but the mechanism behind this pathology is not well understood. Using a novel technique to measure subtle pH differences in the lysosome, the authors examined the lysosomal pH found in skin fibroblasts of PS1 patients and found a slight alkalization of lysosomal pH previously undetectable with other measurements of intracellular pH. The expression levels of both mRNA and protein for genes involved in autophagy were shown to be increased in the PS1 fibroblasts, suggesting that a lysosomal pH compensation mechanism may explain the delay in pathology of a PS1 mutation. In particular, lysosomal alkalization impaired the maturation process of cathespin D, a lysosomal protease. The authors introduced cAMP to the PS1 fibroblasts to re-acidify lysosomal pH, resulting in partial rescue of cathepsin D maturation and autophagic function. This suggests that cAMP or another small molecule may acidify lysosomal pH and serve as an avenue for treatment of early-onset Alzheimer’s disease caused by PS1 mutation.

or, technically, 
Stress-induced CDK5 activation disrupts axonal transport via Lis1/Ndel1/Dynein [See the original abstract on PubMed]

Authors: Eva Klinman, Erika L. Holzbaur

Brief prepared by: Eva Klinman
Brief approved by: Felicia Davatolhagh
Section Chief: Alyse Thomas
Date posted: May 13, 2016 

Brief in Brief (TL;DR)

What do we know: Cargos move up and down axons normally, and this is disrupted when axons become stressed or ill (like in ALS, Alzheimer’s, and Parkinson’s). 

What don’t we know: We don’t understand what regulates the movement along the axon (what controls the motor proteins dynein and kinesin), and how we can fix this process when it goes wrong. 

What this study shows: This study shows how CDK5 over-activation causes disrupted cargo transport through changes in motor protein activity. CDK5 alters motor proteins indirectly, through proteins Ndel1 and Lis1. Reducing CDK5 activity restores cargo transport to normal in mouse models of ALS. 

What we can do in the future because of this study: We can figure out what else is affecting cargo transport in neurons (it isn’t just CDK5!), and in the future attempt to treat sick mice by reducing CDK5 to see if they live longer. 

Why you should care: Understanding how tiny cargo move in neurons is awesome! Also, if we can figure out how disrupted cargo transport contributes to disease, we can develop better treatments.

Brief for Non-Neuroscientists

Neurons are the longest cells in the body, with axons that can stretch from your spine to your foot. Proteins and organelles made in the cell body need to be transported to the end of the axon (led by the motor protein kinesin), and old organelles need to be transported back up the axon to be degraded (dragged along behind the motor protein dynein). This transport up and down the axon is disrupted in neurodegenerative diseases like ALS, Alzheimer’s, and Parkinson’s. Scientists do not know how exactly transport is being disrupted, or what we can do to fix it. We found that a neuronal-specific kinase, CDK5, which is over-activated in all of these diseases, is responsible for disrupting transport. High activity of CDK5 causes organelles to wiggle back-and-forth rather than moving smoothly. However, this kinase does not phosphorylate either motor protein directly, rather, we found that it acts on Ndel1, a protein which binds another protein (Lis1) to interfere with dynein-drive transport from the end of the axon to the cell body. Therefore, CDK5 acts indirectly to disrupt transport. Reducing CDK5 activity in neurons from an ALS mouse model helped restore transport.

Brief for Neuroscientists

Axonal transport is disrupted in neurodegenerative disease, but we don’t know how transport is regulated in healthy or diseased neurons. The kinase CDK5 is overactivated in stressed neurons because its normal activator (p35, membrane bound) is cleaved (p25, membrane-free), and this cleavage product is spatially and temporally deregulated. We found that expressing the stress activator (p25) in healthy neurons caused disruption of transport for a wide range of cargos including lysosomes, autophagosomes, mitochondria, and signaling endosomes. Previous labs have determined that CDK5 does not directly phosphorylate kinesin or dynein. However, we determined that CDK5 phosphorylates Ndel1, which binds Lis1 to regulate the retrograde processivity of dynein. Without Ndel1, CDK5 cannot disrupt motility. Moreover, similar disruptions are found in neurons taken from SOD1 mice, an ALS mouse model. Reducing CDK5 activity in these neurons returns transport to normal, implying that CDK5 over-activity is responsible for disrupting transport.

or, technically, 
The regulation of autophagosome dynamics by huntingtin and HAP1 is disrupted by expression of mutant huntingtin, leading to defective cargo degradation. [See the original abstract on PubMed]

Authors: Yvette C. Wong, Erika L. Holzbaur

Brief prepared by: Sarah Ly
Brief approved by: Isaac Perron
Section Chief: Alyse Thomas
Date posted: May 3, 2016

Brief in Brief (TL;DR)

What do we know: Healthy cells need to get rid of materials that they can no longer use. In Huntington’s disease (HD), cells aren’t able to get rid of unwanted stuff and scientists think this is one reason why the disease destroys the brain. 

What don’t we know: The specific ways that HD causes cells to be unable to get rid of unwanted material. 

What this study shows: In HD, what may be happening is that cells with mutated htt protein can’t transport unwanted stuff to where it needs to go because normally in a healthy cell the htt protein and its partner protein help move junk from one end of the neuron (the tip of the axon) to the other end (the cell body). 

What we can do in the future because of this study: We can continue to study cell transport and find new ways to treat HD. 

Why you should care: There is currently no cure for HD. By improving our understanding of what goes wrong in the brain during HD, scientists can work towards developing new treatments for the disease.

Brief for Non-Neuroscientists

Healthy cells need to get rid of materials that they can no longer use. Huntington’s disease (HD) is a devastating disease where sufferers lose brain function and are unable to control their own body movements. In the brains of patients with HD, the neurons — the main cells in the brain — aren’t able to get rid of unwanted junk or waste. Scientists believe this may be the reason why neurons die in the brain in HD. In a healthy neuron, waste gets packaged and transported from one end of the cell (the tip of the axon) back to the other end of the cell (the cell body). Scientists are still trying to figure out what specifically goes wrong in this process that causes cells to die in HD. This study shows that normal huntingtin protein helps move things from the axon to the cell body with the help of a partner protein. Thus, having abnormal huntingtin protein, which is the cause of HD, prevents cells from moving waste back to the cell body and this waste is now not efficiently degraded. This is important to know because it shows us that in HD, the problem with getting rid of junk is that the junk can’t travel to where it needs to go! If cells are no longer able to move stuff that it no longer needs to places where it can get broken down, these things can build up and cause cells to die.

Brief for Neuroscientists

Healthy cells must regularly degrade nonessential proteins in a process known as autophagy. Defects in autophagy have been implicated in the neurodegenerative disorder Huntington’s disease (HD), which is caused by a polyglutamine expansion in the huntingtin (htt) gene. The precise mechanisms that underlie autophagosomal defects in HD are not fully understood. In healthy neurons, autophagosomes form at the axon tip and are transported toward the cell body. By live-imaging cells with GFP-labeled autophagosomes, we found that both the htt protein and its adaptor protein huntingtin-associated protein-1 (HAP1) physically associate with autophagosomes in neurons and are necessary for proper retrograde transport of autophagosomes along the axon. This retrograde transport is impaired when neurons express the mutant htt protein. The expression of mutant htt in neurons is also associated with the accumulation of dysfunctional mitochondrial cargo within the autophagosomes, suggesting that defective autophagosome transport is linked to defects in autophagic degradation. The role of htt and HAP1 in promoting transport of autophagosomes may explain how mutations in htt contribute to neurodegeneration and cell death in HD.

or, technically, 
Electrophysiological evidence for functionally distinct neuronal populations in the human substantia nigra. [See the original abstract on PubMed]

Authors: Ashwin G. Ramayya, Kareem A. Zaghloul, Christoph T. Weidemann, Gordon H. Baltuch and Michael J. Kahana

Brief prepared by: Yin Li
Brief approved by: Hannah Shoenhard
Section Chief: Ryan Natan
Date posted: July 12, 2016 

Brief in Brief (TL;DR)

What do we know: The brain area called the substantia nigra (SN) plays important roles in trial-and-error learning and the control of movement. The movement disorder Parkinson's disease is caused by the loss of SN cells that release dopamine, known as DA cells. The SN also contains a different type of cells known as GABA cells. From animal studies, it is known that DA and GABA cells have different functions in the SN. 

What don’t we know: Whether, in the human SN, these two cell types also serve different functions. 

What this study shows: When humans play a game that involves trial-and-error learning, DA and GABA cells respond differently to rewarding experiences. 

What we can do in the future because of this study: Having established that there are distinct groups of neurons, we can begin to explore how they each contribute to normal and abnormal brain function. 

Why you should care: Dysfunction of the SN occurs in many brain disorders, including Parkinson's disease (in which DA cells die) and schizophrenia. Understanding the normal functions of the cells that make up the SN can thus help us understand and potentially treat these brain disorders.

Brief for Non-Neuroscientists

The substantia nigra (SN) has at least two neuron types: DA neurons, which release the neurotransmitter dopamine, and GABA neurons, which release the neurotransmitter GABA. Animal studies indicate that these cells play distinct roles in a variety of tasks, including trial-and-error learning and motor control. Animal studies have also shown that these neurons have different electrical properties. For example, DA cells tend to fire more slowly than GABA cells. In this study, the scientists recorded from the SN of human patients undergoing surgery for Parkinson's disease while the subjects played a video game involving trial-and-error learning. In the past, it has been difficult to study the activity of DA cells versus GABA cells in the human brain because these cells are anatomically intermingled. This challenge was overcome by using the distinct electrical properties of DA and GABA cells in the SN, rather than physical features or location, to classify them. They found that human DA and GABA cells do indeed respond differently when patients encounter positive experiences in their video game. This result confirms that there are two subpopulations of cells with different roles in the human SN and gives neuroscientists a new tool to distinguish these subpopulations in future studies.

Brief for Neuroscientists

The substantia nigra (SN) is composed of two anatomically intermingled subareas known as the pars compacta and the pars reticulata, which are key nodes of the basal ganglia system for learning from trial-and-error (reinforcement learning) and controlling movement. Pars compacta and pars reticulata are preferentially enriched for neurons that release the neurotransmitters DA and GABA, respectively. Non-human studies indicate that DA and GABA cells in these two areas play functionally distinct roles in the basal ganglia; however, it is not known whether the same is true in the human brain, partly because these cells tend to be anatomically intermingled. In this study, Ramayya and colleagues recorded from the SN of human patients undergoing surgery for Parkinson's disease, which involves placement of microelectrodes near the SN. The patients played a video game in which they had to learn by trial-and-error which symbols on the screen would give them the most number of virtual points. After each choice, subjects were given either positive or negative feedback. Recorded cells were classified as DA or GABA cells based on their firing rate and waveform: from animal studies, DA cells are known to have low firing rates and wide spike waveforms, whereas GABA cells have tonically high firing rates and narrower spike waveforms. They found that DA and GABA cells differed in their responses to positive feedback in the game. Whereas DA cells tended to respond with a quick burst of activity soon after feedback (within ~250-500 ms), GABA cells responded more slowly, with elevated firing rates that occurred up to 1000 ms after feedback. These results confirm the existence of two functionally distinct subpopulations of neurons in the human substantia nigra and suggest that a combination of firing rate and waveform may be a useful way to classify DA and GABA cells in vivo for future studies.

or, technically, 
Behavioral correlates of auditory streaming in rhesus macaques. [See the original abstract on PubMed]

Authors: Kate L. Christison-Lagay, Yale E. Cohen

Brief prepared by: Kate Christison-Lagay
Brief approved by: Bri Jeffrey
Section Chief: Ryan Natan
Date posted: May 3, 2016 

Brief in Brief (TL;DR)

What do we know: We can hear individual sounds from a background of sounds; we know some stuff about noises that help us hear sounds separately from other sounds

What don’t we know: How the brain does this; if animals hear the same way

What this study shows: Animals (monkeys) hear sounds the same way as people

What we can do in the future because of this study: Record from neurons in different parts of the brain to see how the brain is figuring out how we hear things in our world

Why you should care: We don’t know how we *normally* perceive sounds, so we don’t really know how we can fix things when stuff goes wrong with our hearing on the brain-side (instead of the ear-side) of things. This helps us figure out how the brain normally hears things, so we can start to address what to do when it’s not working normally.

Brief for Non-Neuroscientists

We hear individual sounds because our brains can either group or separate noises in our environment--a process we call ’auditory streaming’. For many years, scientists have used a particular stimulus--one in which two tones alternate--to figure out what cues in sounds help us group them together or separate them apart. However, because we cannot record from neurons (cells in the brain) in people, and because it is hard to train animals to do this task, we do not know what the brain is doing while we hear this set of sounds. Before we can record from neurons in animals, we have to make sure that they hear and decide about the sounds in this task the same way people do. We found that monkeys make the same kind of decisions in this task as people. We can now record from neurons while monkeys are doing this task, and determine how neurons in different parts of the brain respond.

Brief for Neuroscientists

Our ability to hear sounds as distinct units arises from our ability to segregate and group acoustic features--a process called streaming. Although an ’auditory streaming’ task has been used extensively to study these perceptual processes in humans, we do not know the neural correlates of this ability, in part because all neurophysiological animal studies using this stimulus have been done while animals are passively listening or sedated. Before using this task to examine the neural correlates of auditory streaming, we had to establish whether animals performed the task similarly to humans. We found that monkeys’ behavioral reports were qualitatively consistent with those of human listeners, thus this task may be used in future neurophysiological studies.