The Connections of Layer 4 Subdivisions in the Primary Visual Cortex (V1) of the Owl Monkey

doi:10.1093/cercor/10.7.644

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Cerebral Cortex, Vol. 10, No. 7, 644-662, July 2000
© 2000 Oxford University Press

The Connections of Layer 4 Subdivisions in the Primary Visual Cortex (V1) of the Owl Monkey

Jamie D. Boyd¹, Julia A. Mavity-Hudson¹ and Vivien A. Casagrande¹^,2^,3

Departments of , ¹ Cell Biology, , ² Psychology and , ³ Ophthalmology and Visual Sciences, Vanderbilt University, Nashville, TN 37232, USA

The primary visual cortex (V1) of primates receives signalsfrom parallel lateral geniculate nucleus (LGN) channels. Thesesignals are utilized by the laminar and compartmental [i.e.cytochrome oxidase (CO) blob and interblob] circuitry of V1to synthesize new output pathways appropriate for the next stepsof analysis. Within this framework, this study had two objectives:(i) to analyze the con- nections between primary input and outputlayers and compartments of V1; and (ii) to determine differencesin connection patterns that might be related to species differencesin physiological properties in an effort to link specific pathwaysto visual functions. In this study we examined the intrinsicinterlaminar connections of V1 in the owl monkey, a nocturnalNew World monkey, with a special emphasis on the projectionsfrom layer 4 to layer 3. Interlaminar connections were labeledvia small iontophoretic or pressure injections of tracers [horseradishperoxidase, biocytin, biotinylated dextrine amine (BDA) or choleratoxin subunit B conjugated to colloidal gold particles]. Ourmost significant finding was that layer 4 (4C of Brodmann) canbe divided into three tiers based upon projections to the superficiallayers. Specifically, we find that 4 ${alpha}$ (4C ${alpha}$ ), 4ß (4Cß)and 4ctr send primary projections to layers 3C (4B), 3Bß(4A) and 3B ${alpha}$ (3B), respectively. Examination of laminar structurewith Nissl staining supports a tripartite organization of layer4. The cortical output layer above layer 3B ${alpha}$ (3B) (e.g. layer3A) does not appear to receive any direct connections from layer4 but receives heavy input from layers 3B ${alpha}$ (3B) and 3C (4B).Some connectional differences also were observed between thesubdivisions of layer 3 and the infragranular layers. No consistentdifferences in connections were observed that distinguishedCO blobs from interblobs or that could be correlated with differencesin visual lifestyle (nocturnal versus diurnal) when comparedwith connectional data in other primates. Re-examination ofdata from previous studies in squirrel and macaque monkeys suggeststhat the tripartite organization of layer 4 and the unique projectionpattern of layer 4ctr are not restricted to owl monkeys, butare common to a number of primate species.

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