Your search keyword '"Kalmbach, Brian"' showing total 9 results

1. Areal specializations in the morpho-electric and transcriptomic properties of primate layer 5 extratelencephalic projection neurons

Author

Dembrow, Nikolai C., Sawchuk, Scott, Dalley, Rachel, Opitz-Araya, Ximena, Hudson, Mark, Radaelli, Cristina, Alfiler, Lauren, Walling-Bell, Sarah, Bertagnolli, Darren, Goldy, Jeff, Johansen, Nelson, Miller, Jeremy A., Nasirova, Kamiliam, Owen, Scott F., Parga-Becerra, Alejandro, Taskin, Naz, Tieu, Michael, Vumbaco, David, Weed, Natalie, Wilson, Julia, Lee, Brian R., Smith, Kimberly A., Sorensen, Staci A., Spain, William J., Lein, Ed S., Perlmutter, Steve I., Ting, Jonathan T., and Kalmbach, Brian E.

Published

2024

2. A suite of enhancer AAVs and transgenic mouse lines for genetic access to cortical cell types

Author

Ben-Simon, Yoav, primary, Hooper, Marcus, additional, Narayan, Sujatha, additional, Daigle, Tanya, additional, Dwivedi, Deepanjali, additional, Way, Sharon W, additional, Oster, Aaron, additional, Stafford, David A, additional, Mich, John K, additional, Taormina, Michael J, additional, Martinez, Refugio A, additional, Opitz-Araya, Ximena, additional, Roth, Jada R, additional, Allen, Shona, additional, Ayala, Angela, additional, Bakken, Trygve E, additional, Barcelli, Tyler, additional, Barta, Stuard, additional, Bendrick, Jacqueline, additional, Bertagnolli, Darren, additional, Bowlus, Jessica, additional, Boyer, Gabriella, additional, Brouner, Krissy, additional, Casian, Brittny, additional, Casper, Tamara, additional, Chakka, Anish B, additional, Chakrabarty, Rushil, additional, Chance, Rebecca K, additional, Chavan, Sakshi, additional, Departee, Maxwell, additional, Donadio, Nicholas, additional, Dotson, Nadezhda, additional, Egdorf, Tom, additional, Gabitto, Mariano, additional, Gary, Amanda, additional, Gasperini, Molly, additional, Goldy, Jeff, additional, Gore, Bryan B, additional, Graybuck, Lucas, additional, Greisman, Noah, additional, Haeseleer, Francoise, additional, Halterman, Carliana, additional, Helback, Olivia, additional, Hockmeyer, Dirk, additional, Huang, Cindy, additional, Huff, Sydney, additional, Hunker, Avery, additional, Johansen, Nelson, additional, Juneau, Zoe, additional, Kalmbach, Brian, additional, Khem, Shannon, additional, Kutsal, Rana, additional, Larsen, Rachael, additional, Lee, Changkyu, additional, Lee, Angus Y, additional, Leibly, Madison, additional, Lenz, Garreck H, additional, Liang, Elizabeth, additional, Lusk, Nicholas, additional, Malone, Jocelin, additional, Mollenkopf, Tyler, additional, Morin, Elyse, additional, Newman, Dakota, additional, Ng, Lydia, additional, Ngo, Kiet, additional, Omstead, Victoria, additional, Oyama, Alana, additional, Pham, Trangthanh, additional, Pom, Christina A, additional, Potekhina, Lydia, additional, Ransford, Shea, additional, Rette, Dean, additional, Rimorin, Christine, additional, Rocha, Dana, additional, Ruiz, Augustin, additional, Sanchez, Raymond E.A., additional, Sedeno-Cortes, Adriana, additional, Sevigny, Joshua P, additional, Shapovalova, Nadiya, additional, Shulga, Lyudmila, additional, Sigler, Ana R, additional, Siverts, La Akea, additional, Somasundaram, Saroja, additional, Stewart, Kaiya, additional, Tieu, Michael, additional, Trader, Cameron, additional, van Velthoven, Cindy T.J., additional, Walker, Miranda, additional, Weed, Natalie, additional, Wirthlin, Morgan, additional, Wood, Toren, additional, Wynalda, Brooke, additional, Yao, Zizhen, additional, Zhou, Thomas, additional, Ariza, Jeanelle, additional, Dee, Nick, additional, Reding, Melissa, additional, Ronellenfitch, Kara, additional, Mufti, Shoaib, additional, Sunkin, Susan M, additional, Smith, Kimberly A, additional, Esposito, Luke, additional, Waters, Jack, additional, Thyagarajan, Bargavi, additional, Yao, Shenqin, additional, Lein, Ed, additional, Zeng, Hongkui, additional, Levi, Boaz P, additional, Ngai, John, additional, Ting, Jonathan T, additional, and Tasic, Bosiljka, additional

Published

2024

3. Morpho-electric diversity of human hippocampal CA1 pyramidal neurons

Author

Mertens, Eline J., primary, Leibner, Yoni, additional, Pie, Jean, additional, Galakhova, Anna A., additional, Waleboer, Femke, additional, Meijer, Julia, additional, Heistek, Tim S., additional, Wilbers, René, additional, Heyer, Djai, additional, Goriounova, Natalia A., additional, Idema, Sander, additional, Verhoog, Matthijs B., additional, Kalmbach, Brian E., additional, Lee, Brian R., additional, Gwinn, Ryder P., additional, Lein, Ed S., additional, Aronica, Eleonora, additional, Ting, Jonathan, additional, Mansvelder, Huibert D., additional, Segev, Idan, additional, and de Kock, Christiaan P.J., additional

Published

2024

4. Integrated multimodal cell atlas of Alzheimer’s disease

Author

Gabitto, Mariano I., Travaglini, Kyle J., Rachleff, Victoria M., Kaplan, Eitan S., Long, Brian, Ariza, Jeanelle, Ding, Yi, Mahoney, Joseph T., Dee, Nick, Goldy, Jeff, Melief, Erica J., Agrawal, Anamika, Kana, Omar, Zhen, Xingjian, Barlow, Samuel T., Brouner, Krissy, Campos, Jazmin, Campos, John, Carr, Ambrose J., Casper, Tamara, Chakrabarty, Rushil, Clark, Michael, Cool, Jonah, Dalley, Rachel, Darvas, Martin, Ding, Song-Lin, Dolbeare, Tim, Egdorf, Tom, Esposito, Luke, Ferrer, Rebecca, Fleckenstein, Lynn E., Gala, Rohan, Gary, Amanda, Gelfand, Emily, Gloe, Jessica, Guilford, Nathan, Guzman, Junitta, Hirschstein, Daniel, Ho, Windy, Hupp, Madison, Jarsky, Tim, Johansen, Nelson, Kalmbach, Brian E., Keene, Lisa M., Khawand, Sarah, Kilgore, Mitchell D., Kirkland, Amanda, Kunst, Michael, Lee, Brian R., Leytze, Mckaila, Mac Donald, Christine L., Malone, Jocelin, Maltzer, Zoe, Martin, Naomi, McCue, Rachel, McMillen, Delissa, Mena, Gonzalo, Meyerdierks, Emma, Meyers, Kelly P., Mollenkopf, Tyler, Montine, Mark, Nolan, Amber L., Nyhus, Julie K., Olsen, Paul A., Pacleb, Maiya, Pagan, Chelsea M., Peña, Nicholas, Pham, Trangthanh, Pom, Christina Alice, Postupna, Nadia, Rimorin, Christine, Ruiz, Augustin, Saldi, Giuseppe A., Schantz, Aimee M., Shapovalova, Nadiya V., Sorensen, Staci A., Staats, Brian, Sullivan, Matt, Sunkin, Susan M., Thompson, Carol, Tieu, Michael, Ting, Jonathan T., Torkelson, Amy, Tran, Tracy, Valera Cuevas, Nasmil J., Walling-Bell, Sarah, Wang, Ming-Qiang, Waters, Jack, Wilson, Angela M., Xiao, Ming, Haynor, David, Gatto, Nicole M., Jayadev, Suman, Mufti, Shoaib, Ng, Lydia, Mukherjee, Shubhabrata, Crane, Paul K., Latimer, Caitlin S., Levi, Boaz P., Smith, Kimberly A., Close, Jennie L., Miller, Jeremy A., Hodge, Rebecca D., Larson, Eric B., Grabowski, Thomas J., Hawrylycz, Michael, Keene, C. Dirk, and Lein, Ed S.

Abstract

Alzheimer’s disease (AD) is the leading cause of dementia in older adults. Although AD progression is characterized by stereotyped accumulation of proteinopathies, the affected cellular populations remain understudied. Here we use multiomics, spatial genomics and reference atlases from the BRAIN Initiative to study middle temporal gyrus cell types in 84 donors with varying AD pathologies. This cohort includes 33 male donors and 51 female donors, with an average age at time of death of 88 years. We used quantitative neuropathology to place donors along a disease pseudoprogression score. Pseudoprogression analysis revealed two disease phases: an early phase with a slow increase in pathology, presence of inflammatory microglia, reactive astrocytes, loss of somatostatin+inhibitory neurons, and a remyelination response by oligodendrocyte precursor cells; and a later phase with exponential increase in pathology, loss of excitatory neurons and Pvalb+and Vip+inhibitory neuron subtypes. These findings were replicated in other major AD studies.

Published

2024

5. Morpho-electric diversity of human hippocampal CA1pyramidal neurons

Author

Mertens, Eline J., Leibner, Yoni, Pie, Jean, Galakhova, Anna A., Waleboer, Femke, Meijer, Julia, Heistek, Tim S., Wilbers, René, Heyer, Djai, Goriounova, Natalia A., Idema, Sander, Verhoog, Matthijs B., Kalmbach, Brian E., Lee, Brian R., Gwinn, Ryder P., Lein, Ed S., Aronica, Eleonora, Ting, Jonathan, Mansvelder, Huibert D., Segev, Idan, and de Kock, Christiaan P.J.

Abstract

Hippocampal pyramidal neuron activity underlies episodic memory and spatial navigation. Although extensively studied in rodents, extremely little is known about human hippocampal pyramidal neurons, even though the human hippocampus underwent strong evolutionary reorganization and shows lower theta rhythm frequencies. To test whether biophysical properties of human Cornu Amonis subfield 1(CA1) pyramidal neurons can explain observed rhythms, we map the morpho-electric properties of individual CA1pyramidal neurons in human, non-pathological hippocampal slices from neurosurgery. Human CA1pyramidal neurons have much larger dendritic trees than mouse CA1pyramidal neurons, have a large number of oblique dendrites, and resonate at 2.9 Hz, optimally tuned to human theta frequencies. Morphological and biophysical properties suggest cellular diversity along a multidimensional gradient rather than discrete clustering. Across the population, dendritic architecture and a large number of oblique dendrites consistently boost memory capacity in human CA1pyramidal neurons by an order of magnitude compared to mouse CA1 pyramidal neurons.

Published

2024

6. Distinctive Physiology of Molecularly Identified Medium Spiny Neurons in the Macaque Putamen

Author

Ting, Jonathan T., Johansen, Nelson J., Kalmbach, Brian E., Taskin, Naz, Lee, Brian, Clark, Jason K., Kendrick, Rennie, Ng, Lindsay, Radaelli, Cristina, Weed, Natalie, Enstrom, Rachel, Ransford, Shea, Redford, Ingrid, Walling-Bell, Sarah, Dalley, Rachel, Tieu, Michael, Goldy, Jeff, Jorstad, Nik, Smith, Kimberly, Bakken, Trygve, Lein, Ed S., and Owen, Scott F.

Abstract

The distinctive physiology of striatal medium spiny neurons (MSNs) underlies their ability to integrate sensory and motor input. In rodents, MSNs have a hyperpolarized resting potential and low input resistance. When activated, they have a delayed onset of spiking and regular spike rate. Here we show that in the macaque putamen, latency to spike is reduced and spike rate adaptation is increased relative to mouse. We use whole-cell brain slice recordings and recover single-cell gene expression using Patch-Seq to distinguish macaque MSN cell types. Species differences in the expression of ion channel genes including the calcium-activated chloride channel, ANO2, and an auxiliary subunit of the A-type potassium channel, DPP10, are correlated with species differences in spike rate adaptation and latency to first spike, respectively. These surprising divergences in physiology better define the strengths and limitations of mouse models for understanding neuronal and circuit function in the primate basal ganglia.

Published

2024

7. Enhancer AAV toolbox for accessing and perturbing striatal cell types and circuits.

Author

Hunker AC, Wirthlin ME, Gill G, Johansen NJ, Hooper M, Omstead V, Taskin N, Weed N, Vargas S, Bendrick JL, Gore B, Ben-Simon Y, Bishaw Y, Opitz-Araya X, Martinez RA, Way S, Thyagarajan B, Lerma MN, Laird W, Sven O, Sanchez REA, Alexander JR, Amaya A, Amster A, Ayala A, Baker PM, Barcelli T, Barta S, Bertagnolli D, Bielstein C, Bishwakarma P, Bowlus J, Boyer G, Brouner K, Casian B, Casper T, Chakka AB, Chakrabarty R, Clark M, Colbert K, Daniel S, Dawe T, Departee M, DiValentin P, Donadio NP, Dotson NI, Dwivedi D, Egdorf T, Fliss T, Gary A, Goldy J, Grasso C, Groce EL, Gudsnuk K, Han W, Haradon Z, Hastings S, Helback O, Ho WV, Huang C, Johnson T, Jones DL, Juneau Z, Kenney J, Leibly M, Li S, Liang E, Loeffler H, Lusk NA, Madigan Z, Malloy J, Malone J, McCue R, Melchor J, Mich JK, Moosman S, Morin E, Naidoo R, Newman D, Ngo K, Nguyen K, Oster AL, Ouellette B, Oyama AA, Pena N, Pham T, Phillips E, Pom C, Potekhina L, Ransford S, Reding M, Rette DF, Reynoldson C, Rimorin C, Rios Sigler A, Rocha DB, Ronellenfitch K, Ruiz A, Sawyer L, Sevigny J, Shapovalova NV, Shepard N, Shulga L, Soliman S, Staats B, Taormina MJ, Tieu M, Wang Y, Wilkes J, Wood T, Zhou T, Williford A, Dee N, Mollenkopf T, Ng L, Esposito L, Kalmbach B, Yao S, Ariza J, Mufti S, Smith K, Waters J, Ersing I, Patrick M, Zeng H, Lein ES, Kojima Y, Horwitz G, Owen SF, Levi BP, Daigle TL, Tasic B, Bakken TE, and Ting JT

Abstract

We present an enhancer AAV toolbox for accessing and perturbing striatal cell types and circuits. Best-in-class vectors were curated for accessing major striatal neuron populations including medium spiny neurons (MSNs), direct and indirect pathway MSNs, as well as Sst-Chodl, Pvalb-Pthlh, and cholinergic interneurons. Specificity was evaluated by multiple modes of molecular validation, three different routes of virus delivery, and with diverse transgene cargos. Importantly, we provide detailed information necessary to achieve reliable cell type specific labeling under different experimental contexts. We demonstrate direct pathway circuit-selective optogenetic perturbation of behavior and multiplex labeling of striatal interneuron types for targeted analysis of cellular features. Lastly, we show conserved in vivo activity for exemplary MSN enhancers in rat and macaque. This collection of striatal enhancer AAVs offers greater versatility compared to available transgenic lines and can readily be applied for cell type and circuit studies in diverse mammalian species beyond the mouse model., Competing Interests: Declaration of interests Authors JTT, BPL, EL, TLD, BTa, HZ, JKM are co-inventors on patent application PCT/US2021/45995 Artificial expression constructs for selectively modulating gene expression in striatal neurons. Authors JTT, BPL, TLD, BTa, TEB are co-inventors on provisional patent application US 63/582,759 Artificial expression constructs for modulating gene expression in the basal ganglia. HZ – is on the Scientific Advisory Board of MapLight Therapeutics, Palo Alto, CA

Published

2024

8. A suite of enhancer AAVs and transgenic mouse lines for genetic access to cortical cell types.

Author

Ben-Simon Y, Hooper M, Narayan S, Daigle T, Dwivedi D, Way SW, Oster A, Stafford DA, Mich JK, Taormina MJ, Martinez RA, Opitz-Araya X, Roth JR, Allen S, Ayala A, Bakken TE, Barcelli T, Barta S, Bendrick J, Bertagnolli D, Bowlus J, Boyer G, Brouner K, Casian B, Casper T, Chakka AB, Chakrabarty R, Chance RK, Chavan S, Departee M, Donadio N, Dotson N, Egdorf T, Gabitto M, Garcia J, Gary A, Gasperini M, Goldy J, Gore BB, Graybuck L, Greisman N, Haeseleer F, Halterman C, Helback O, Hockemeyer D, Huang C, Huff S, Hunker A, Johansen N, Juneau Z, Kalmbach B, Khem S, Kussick E, Kutsal R, Larsen R, Lee C, Lee AY, Leibly M, Lenz GH, Liang E, Lusk N, Malone J, Mollenkopf T, Morin E, Newman D, Ng L, Ngo K, Omstead V, Oyama A, Pham T, Pom CA, Potekhina L, Ransford S, Rette D, Rimorin C, Rocha D, Ruiz A, Sanchez REA, Sedeno-Cortes A, Sevigny JP, Shapovalova N, Shulga L, Sigler AR, Siverts LA, Somasundaram S, Stewart K, Szelenyi E, Tieu M, Trader C, van Velthoven CTJ, Walker M, Weed N, Wirthlin M, Wood T, Wynalda B, Yao Z, Zhou T, Ariza J, Dee N, Reding M, Ronellenfitch K, Mufti S, Sunkin SM, Smith KA, Esposito L, Waters J, Thyagarajan B, Yao S, Lein ES, Zeng H, Levi BP, Ngai J, Ting J, and Tasic B

Abstract

The mammalian cortex is comprised of cells classified into types according to shared properties. Defining the contribution of each cell type to the processes guided by the cortex is essential for understanding its function in health and disease. We used transcriptomic and epigenomic cortical cell type taxonomies from mouse and human to define marker genes and putative enhancers and created a large toolkit of transgenic lines and enhancer AAVs for selective targeting of cortical cell populations. We report evaluation of fifteen new transgenic driver lines, two new reporter lines, and >800 different enhancer AAVs covering most subclasses of cortical cells. The tools reported here as well as the scaled process of tool creation and modification enable diverse experimental strategies towards understanding mammalian cortex and brain function.

Published

2024

9. Expansion-assisted selective plane illumination microscopy for nanoscale imaging of centimeter-scale tissues.

Author

Glaser A, Chandrashekar J, Vasquez S, Arshadi C, Ouellette N, Jiang X, Baka J, Kovacs G, Woodard M, Seshamani S, Cao K, Clack N, Recknagel A, Grim A, Balaram P, Turschak E, Hooper M, Liddell A, Rohde J, Hellevik A, Takasaki K, Erion Barner L, Logsdon M, Chronopoulos C, de Vries S, Ting J, Perlmutter S, Kalmbach B, Dembrow N, Tasic B, Reid RC, Feng D, and Svoboda K

Abstract

Recent advances in tissue processing, labeling, and fluorescence microscopy are providing unprecedented views of the structure of cells and tissues at sub-diffraction resolutions and near single molecule sensitivity, driving discoveries in diverse fields of biology, including neuroscience. Biological tissue is organized over scales of nanometers to centimeters. Harnessing molecular imaging across intact, three-dimensional samples on this scale requires new types of microscopes with larger fields of view and working distance, as well as higher throughput. We present a new expansion-assisted selective plane illumination microscope (ExA-SPIM) with aberration-free 1×1×3 μm optical resolution over a large field of view (10.6×8.0 mm 2 ) and working distance (35 mm) at speeds up to 946 megavoxels/sec. Combined with new tissue clearing and expansion methods, the microscope allows imaging centimeter-scale samples with 250×250×750 nm optical resolution (4× expansion), including entire mouse brains, with high contrast and without sectioning. We illustrate ExA-SPIM by reconstructing individual neurons across the mouse brain, imaging cortico-spinal neurons in the macaque motor cortex, and visualizing axons in human white matter.

Published

2024