Mastodawn

New preprint: "Stoichiometric transcription factor partnerships control GABAergic neuron fate allocation."

Cell identity in development is often described as a combinatorial transcription factor "code." We find it is also quantitative: not only which factors are present, but their relative abundance, can shape a cell's fate.

In the developing basal ganglia, a pool of undifferentiated progenitors gives rise to several GABAergic neuron types, including D1 and D2 medium spiny neurons. Using our in vivo clonal perturbation sequencing and clone2vec, we find that losing SP9 shifts the clonal fate bias of progenitors from D2 neurons toward other GABAergic fates.

The readout uses two modes of genome binding: at GC-rich promoters SP9 binds DNA directly and activates; at distal enhancers it binds indirectly, tethered by DLX, acting as a combinatorial repressor with the NuRD complex. When DLX is in excess it sequesters SP9 away from its activating targets, so a graded shift in the SP9:DLX ratio becomes a discrete fate choice. An SP9 variant linked to neurodevelopmental disorders impairs the activator mode.

With thanks to the team, collaborators, and to #SFARI, the #DFG and the #NLMFF.

https://doi.org/10.64898/2026.05.25.727662

#newsmayerlab #neuroscience #genomics #devbio

Stoichiometric transcription factor partnerships control GABAergic neuron fate allocation

Combinatorial transcription factor (TF) codes specify neuronal fates, yet how quantitative differences in interacting TFs shape these decisions remains unresolved. We address this in the developing basal ganglia, where a pool of undifferentiated progenitors gives rise to both D1 and D2 medium spiny neurons (MSNs). Combining sparse in vivo CRISPR perturbation, lineage barcoding, and single-cell transcriptomics in mice, we find that loss of Sp9 shifts clonal fate bias from D2 toward D1 MSNs and intercalated cells. Mechanistically, chromatin profiling and biochemical assays show that at GC-rich promoters, SP9 binds DNA directly and activates transcription. At distal enhancers, SP9 binds indirectly, tethered by DLX factors, represses activity, and associates with the NuRD corepressor complex. The relative abundance of SP9 and DLX selects between these modes. These findings extend the combinatorial TF code beyond factor identity to relative proportions, with relevance to neurodevelopmental disorders. ### Competing Interest Statement The authors have declared no competing interest. Deutsche Forschungsgemeinschaft, https://ror.org/018mejw64, 549328218 Simons Foundation, https://ror.org/01cmst727, SFI-AN-AR-Pilot-00009814 Nancy Lurie Marks Family Foundation European Molecular Biology Organization, https://ror.org/04wfr2810, EMBO Young Investigator Programme

bioRxiv

Christian Mayer Jun 2

I had a wonderful time visiting INMED in Marseille — many thanks to Stéphane Bugeon for the invitation.

I’m grateful for the opportunity to present our group’s research and for many inspiring conversations with the fantastic scientists there.

A great institute in a beautiful place!
#newsmayerlab

Christian Mayer May 28

New preprint from the lab!

How do brain progenitors choose between D1 and D2 medium spiny neurons? We find the *relative levels* of SP9 and DLX TFs tip the balance: SP9 activates D2 genes at promoters, and represses D1 enhancers via DLX/NuRD.

Proud of the team — combining sparse in vivo CRISPR, lineage barcoding, scRNA-seq, ChIP-seq, CUT&RUN and proteomics for mechanistic depth in in vivo functional genomics.

🔗 [https://doi.org/10.64898/2026.05.25.727662]

#newsmayerlab #Neuroscience #DevBio #Transcription #bioRxiv

Christian Mayer May 6

Excellent science and great discussions at the GOLGI III conference in Bordeaux. Many thanks to the organizers and everyone involved for a very engaging meeting in a close and collegial atmosphere. #newsmayerlab

Christian Mayer Mar 15

Excited to be in New York this week for the SFARI Investigator Meeting.

Looking forward to discussions on neurodevelopmental disorders, gene regulation, and developmental mechanisms — and to catching up with many colleagues and collaborators. #newsmayerlab

Christian Mayer Dec 17, 2025

Many thanks to Stéphanie Baulac and Bassem Hassan for hosting me at ICM and for the opportunity to present our lab’s work. Great discussions and a very enjoyable visit to Paris. #newsmayerlab

Christian Mayer Dec 11, 2025

Wrapping up 2025 with a small holiday get-together over dinner. Thanks to everyone who made this year inspiring. #newsmayerlab

Christian Mayer Nov 1, 2025

🎉 Congratulations to Ann Bright!
Our postdoc Ann Bright was invited to present her research at the 2025 SYNAPSES Symposium at Yale University — a prestigious and highly selective event showcasing outstanding postdoctoral neuroscientists from around the world.

We’re proud to see her work recognized on this international stage! 👏
#Postdoc #SynapsesSymposium #NewsMayerlab

Christian Mayer Oct 12, 2025

Was the layered cortex really unique to amniotes? Salamanders, our anamniote cousins, suggest otherwise.

In a new preprint from Maria Antonietta Tosches’ lab (first author Astrid Deryckere), we show that salamanders share core developmental logic with mammals — but with an ancestral outside-in sequence.

Clonal lineage tracing in salamanders reveals that both superficial and deep-layer neurons arise from the same multipotent radial glia.

Glad to have contributed to this work.
#neuroscience #development #evolution #anamniotes #NewsMayerlab

https://www.biorxiv.org/content/10.1101/2025.10.01.679862v1

A conserved logic for the development of cortical layering in tetrapods

The evolutionary origin of the cerebral cortex, a brain region typically defined by the presence of neuronal layers, remains elusive. While mammals and reptiles have a layered cortex, the amphibian pallium (dorsal telencephalon) is considered unlayered. Here, we identify distinct superficial- and deep-layer neurons in the salamander pallium. Like in mammals, these layers develop sequentially from multipotent radial glia and intermediate progenitor cells. Using lineage tracing and scRNA-seq, we reveal conserved principles of cortical development, including the temporal patterning of radial glia and the association of neuronal birthdate, molecular identity, and projection type. Our findings indicate that the mammalian cortex evolved from this ancestral developmental template through the inversion of the corticogenesis gradient, from outside-in to inside-out, and the diversification of neuronal differentiation programs. ### Competing Interest Statement In the past 3 years, RS has received compensation from Bristol Myers Squibb, ImmunAI, Resolve Biosciences, Nanostring, 10x Genomics, Parse Biosciences and Neptune Bio. RS is a co-founder and equity holder of Neptune Bio. National Institute of General Medical Sciences, R35GM146973 National Human Genome Research Institute, 1RM1HG011014 McKnight Foundation, https://ror.org/003ghvj67, MEFN CU20-0049 Rita Allen Foundation, https://ror.org/0515k5w36, GA\_032522\_FE Chan Zuckerberg Initiative (United States), https://ror.org/02qenvm24, 2023-331758 Deutsche Forschungsgemeinschaft, 549328218 European Molecular Biology Organization, https://ror.org/04wfr2810, ALTF 874-2021 U.S. National Science Foundation, https://ror.org/021nxhr62, GRFP Anusandhan National Research Foundation, ANRF/ECRG/2024/006839/LS TiH Foundation, TIH0018-002

bioRxiv

Christian Mayer Oct 12, 2025

🎉 Big congratulations to Yana Kotlyarenko for successfully defending her PhD!
She carried out her research project in our lab, and it’s been a joy to see her science and ideas grow. Wishing her all the best for the next steps! 🌟

#PhDDefense #NewsMayerlab