The broad objective of this research program is to understand how basal forebrain (BF) cholinergic (BFC) and non-cholinergic neurons are organized to modulate specific cortical regions. Despite its involvement in cortical activation, attention, and memory, the functional details of the BF are not well understood due to the anatomical complexity of the region. Patients with Alzheimer's disease and related dementias have a significant decrease of acetylcholine in the cortex and show pathological changes in cholinergic neurons in the BF. Thus, a complete understanding of its functional organization is warranted. The central hypothesis of this application is that cholinergic neurons constitute local ensembles in the BF ('cell clusters') that via local collaterals and/or common inputs with their projections to cortical areas provide the neural basis of a distributed functional network to selectively modulate cognitive processes. We will test this hypothesis in 4 interrelated Specific Aims using traditional and monosynaptic viral tracing, computational analysis of large-scale networks, in vitro patch-clamp recording of BF neurons, and high-resolution monitoring of cortical network activity in freely-moving rats with optogenetic stimulation of defined BF cholinergic neurons.
In Aim 1 we will build up a relatively complete database with 200 ?m resolution of mapped BF cholinergic and non-cholinergic neurons using conventional retrograde tracing techniques. Cholinergic clusters will be defined in the resulting 'database' and in the cluster volume significant association of projection cell populations will be determined.
In Aim 2 we will validate of the functional significance of the specific organization of the BFC system in wake-behaving rats. With newly developed multi-array silicon probes implanted into two specific cortical areas and light-assisted perturbation of various cholinergic cell groups in ChAT-Cre rats, in which cholinergic cells were transfected to express channelrhodopsin (ChR2), we will determine the emerging cholinergic ensembles in the BF and their effect on the functional connectivity of various large-scale cortical networks during various brain states.
In Aim 3 we will define the input to cholinergic neurons in various subdivisions of the BF using commercially available Cre-dependent AAV helper viruses (AAV-EF1a-FLEX- TVAmCherry and AAV-CA-FLEX-RG) and a replication deficient rabies vector (RV: EnvA G-deleted Rabies- eGFP).
In Aim 4 we will determine, using in vitro patch clamp recording and retrograde tracing in ChAT-cre X ChAT-eGFP crossbred mice, how does the system of early (EF) and late firing (LF) cholinergic neurons and local cholinergic axon arborizations fit into the global organization of the BFC system. The in vivo large-scale, high-density recording design that is built on a realistic forebran model will lead to substantially improved animal models for addressing function in behavioral studies. Concomitantly, it will facilitate the understanding of the aberrant processing in basalo-cortical networks and may help the development of new treatment strategies to ameliorate the cognitive symptoms in Alzheimer's and related disorders.

Public Health Relevance

Cholinergic cells, which are widely distributed in the basal forebrain (BF), provide the majority of acetylcholine found in the cerebral cortex. This highly complex brain region has been implicated in a range of behaviors, including cortical activation, attention, motivation and memory, but the functional details are not well understood. Patients with Alzheimer's disease and in related dementias have a significant decrease of acetylcholine in the cortex and show pathological changes in cholinergic BF neurons. Part of the difficulty in understanding the role of the BF, as well as the processing characteristics of these disorders lies in the anatomical complexity of the region. The overall goal of this application is to improve our knowledge of the functional organization of the BF. The results will lead to more realistic animal models for addressing function in behavioral studies. Concomitantly, it will facilitate the understanding of the aberrant processing in basalo-cortical networks and may help the development of new treatment strategies to ameliorate the cognitive symptoms in these disorders.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS023945-25
Application #
9211397
Study Section
Pathophysiological Basis of Mental Disorders and Addictions Study Section (PMDA)
Program Officer
Corriveau, Roderick A
Project Start
1986-08-01
Project End
2020-01-31
Budget Start
2017-02-01
Budget End
2018-01-31
Support Year
25
Fiscal Year
2017
Total Cost
$421,521
Indirect Cost
$146,968
Name
Rutgers University
Department
Other Basic Sciences
Type
Schools of Arts and Sciences
DUNS #
130029205
City
Newark
State
NJ
Country
United States
Zip Code
07102
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Lammers, Florian; Borchers, Friedrich; Feinkohl, Insa et al. (2018) Basal forebrain cholinergic system volume is associated with general cognitive ability in the elderly. Neuropsychologia 119:145-156
Yuan, Rui; Biswal, Bharat B; Zaborszky, Laszlo (2018) Functional Subdivisions of Magnocellular Cell Groups in Human Basal Forebrain: Test-Retest Resting-State Study at Ultra-high Field, and Meta-analysis. Cereb Cortex :
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Chavez, Candice; Zaborszky, Laszlo (2017) Basal Forebrain Cholinergic-Auditory Cortical Network: Primary Versus Nonprimary Auditory Cortical Areas. Cereb Cortex 27:2335-2347
Zhang, Sheng; Hu, Sien; Fucito, Lisa M et al. (2017) Resting-State Functional Connectivity of the Basal Nucleus of Meynert in Cigarette Smokers: Dependence Level and Gender Differences. Nicotine Tob Res 19:452-459
Ovsepian, Saak V; O'Leary, Valerie B; Zaborszky, Laszlo (2016) Cholinergic Mechanisms in the Cerebral Cortex: Beyond Synaptic Transmission. Neuroscientist 22:238-51

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