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Cutting Edge: MHC Class I–Ly49 Interaction Regulates Neuronal Function

Ofer Zohar^1,*, Yoram Reiter, Jack R. Bennink, Avital Lev, Sebastiano Cavallaro, Sabrina Paratore, Chaim G. Pick^¶, Gary Brooker^|| and Jonathan W. Yewdell

^* Blanchette Rockefeller Neurosciences Institute, Johns Hopkins University Montgomery County Campus, Rockville, MD 20850; Faculty of Biology, Technion, Israel Institute of Technology, Haifa, Israel; Laboratory of Viral Diseases, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, Maryland 20892; Functional Genomics Center, Institute of Neurological Sciences, Italian National Research Council, Catania, Italy; ^¶ Department of Anatomy and Anthropology, Tel-Aviv University Sackler School of Medicine, Tel-Aviv, Israel; and ^|| Department of Chemistry, Johns Hopkins University Microscopy Center, Montgomery County Campus, Rockville, MD 20850

	Abstract

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MHC class I molecules (MHC-I) have been implicated in nervous system development in the mouse. In this study we present evidence for the interaction of MHC-I with the NK cell receptor Ly49 in primary cortical neuronal cultures. We show that MHC-I and Ly49 are expressed on neuronal soma and axon surfaces, with Ly49 also present on dendrites. Anti-MHC-I Abs reduce synapsin-I expression and enhance neurite outgrowth and neuronal death. Conversely, anti-Ly49 mAbs increase synapsin-I expression, reduce neurite outgrowth, and promote neuron viability. Because we show that Ly49 genes are selectively expressed in the adult brain, these findings suggest an unsuspected role for the MHC-I-Ly49 interaction in the development and function of the brain.

	Introduction

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Major histocompatibility complex class I (MHC-I)² molecules play a key role in immunosurveillance by T_CD8⁺ and NK cells. In mice, many NK receptors belong to the Ly49 gene family (1, 2). MHC-I is a ligand for many Ly49 gene products, with some interactions leading to NK activation and others to NK inhibition. The CNS has been classically considered a "privileged site" with limited MHC-I expression. Recent findings, however, suggest a role for MHC-I in neuronal biology in establishing and maintaining neuronal synapses (3, 4, 5, 6, 7, 8, 9).

The function of class I molecules in the CNS implies a specific interaction between MHC-I and a receptor. Because class I genes are typically the most variable genes expressed by vertebrates, class I receptors in the CNS should be molecules that interact with MHC-I in an allomorph-independent manner. One such group of molecules consists of the Ly49 gene products. In this study, we examine the function of MHC-I in the growth and synapse formation of embryonic neuronal cells ex vivo and provide the initial evidence for the potential role of Ly49 gene products as class I receptors in the CNS.

	Materials and Methods

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Primary cortical neuronal cultures

Primary E16 cortical neuronal cultures from C57BL/6J (B6) or BALB/cJ (Jax mice; The Jackson Laboratory) were prepared as described (10). Neurobasal growth medium was supplemented with the proliferation inhibitor fluorodeoxyuridine (100 µM) to minimize glial cells.

Chemicals and antibodies

We used the following Abs: B22.249 (H-2D^b), HB.176 (H-2K^b), D7 and F9 (anti-H-2^b Fabs; Ref. 11), TW2.3 (vaccinia virus), 4D11 (Ly49), G7 (Thy1) (both BD Pharmingen), AB5852 (Shank1a), AB5220 (GAP-43) (both Millipore), A6442 (synapsin-I) (Invitrogen), FITC-conjugated SIINFEKL, and nonconjugated RGYVYQGL (Biological Resources Branch, National Institute of Allergy and Infectious Diseases, Bethesda, MD; Ref. 12).

In situ hybridization

cDNA corresponding to Ly49A mRNA (provided by Dr. W. Yokoyama) was Cy3-cytidine 5'-triphosphate-labeled using a pCRII-TOPO vector (Invitrogen) (forward primer: 5'-TAACTGCAGCACCACGCAAAGTGACGTCAA-3'; reverse primer: 5'-TTCTGTTATGGTATAAAATGTT-3') as described (13). Cy3-labeled Ly49A probe was hybridized with paraformaldehyde-fixed brain slices (12 µm) and imaged (5-µm section resolution; GenePix 4100A, Molecular Devices). No signal was detected from control hybridizations with either sense riboprobe or slices pretreated with RNase before antisense hybridization.

Treatment of cells, immunohistochemistry, and microscopy

Neurons were incubated with the following Abs for 1, 5, or 13 days: H-2D^b H-2K^b (2 or 4 µg/ml in B6 and 4 µg/ml in BALB mice), H-2D^b and H-2K^b together (2 or 4 µg/ml in B6), Ly49G2 (0.1, 0.2, or 1 µg/ml in B6), vaccinia (4 µg/ml in B6), Thy1 (4 µg/ml in B6), and D7 or F9 (4 µg/ml in B6) for 5 days only. Abs were added every 3 to 4 days starting the day after seeding. Cells were either permeabilized with acetone/methanol (50:50%; v/v) for 2 min or gently fixed with 3% paraformaldehyde in PBS for 10 min. Permeabilized neurons were incubated with Zenon-Alexa Fluor 488-labeled (Invitrogen) GAP-43 and their nuclei were stained with benzimide (1 µM; Sigma-Aldrich). Fixed neurons were incubated with appropriate Abs and neuronal distribution was revealed using the following secondary Abs (The Jackson Laboratory): F9- Cy3 labeled goat anti-human, Ly49G2/A-Cy2-labeled goat anti rat, synapsin-I, and Shank1a-Cy5-labeled goat anti-rabbit Abs. To localize the peptide receptive H-2K^b molecules, cultures were incubated with human β_2-microglobulin (5 µg/ml) overnight before 0.5 h of incubation with SIINFEKL-FITC (1 µM) on ice followed by paraformaldehyde fixation.

Coverslips were slide mounted and imaged using confocal microscopy (Pathway HT; BD Biosciences). Cell survival and neurite outgrowth were analyzed from 4 x 4 montages acquired from each coverslip (2.15 mm² each; x20 original magnification). Gap-43, Ly49G2, Shank1a, synapsin-I, and MHC-I distribution were determined using Plan Apo x63 objective (Zeiss). Cell survival was determined by comparing the average number of nuclei per frame for each treatment to untreated neurons and to other concentrations of the same Ab (192 frames/treatment/day; Student’s t test.) Neurite outgrowth was assessed by a modified Sholl method (14) in which three horizontal lines were drawn at 25, 50, and 75% of each frame height and the numbers of neurites crossing these lines were counted and summed per the frame. The crossing number per frame was averaged for each treatment and normalized for cell number by dividing the line crossing number by the nuclei number. Statistical analysis was done as above (192 frames/treatment/day).

	Results and Discussion

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We cultured primary embryonic cortical neurons from B6 mice for 1–5 days and localized MHC-I molecule with the F9 Fab specific for K^b and D^b. F9 bound to cell bodies and axons of 1-day-old neurons, suggesting a possible role in differentiation (red in Fig. 1A). A similar staining pattern was observed using the well-characterized mAbs specific for H-2D^b (B22.249) or H-2K^b (HB.176) (Refs. 15 and 16 and data not shown). Neuronal K^b expression was further verified using the K^b binding peptide SIINFEKL-FITC (Fig. 1B). Staining was specifically inhibited by a competing K^b binding peptide. Notably, axonal staining is punctate in a pattern similar to that of the staining of synaptic components. In 5-day-old neurons, Ab stains showed similar pattern but with more variable stain intensity (not shown).

View larger version (61K): [in this window] [in a new window]   FIGURE 1. MHC-I and Ly49 distribution and expression in cultured cortical neurons and their mRNA expression in the adult mouse brain. A, Codistribution of Abs specific for MHC I (red) and NK receptor Ly49G2 (green). In 1-day neurons MHC-I and Ly 49 colocalize (yellow) in somas and in some axonal regions. MHC-I primarily stains neurites in a clear punctate manner while Ly49 stains axons and dendrites. B, Distribution of SIINFEKL-FITC (blue; overlaid on the transmitted light image of the neurons in gray) in 1-day cell bodies and axons. C, MHC-I (blue) and synapsin I (red) show colocalization in cell bodies (purple) whereas in the axons they show alternate punctate distribution. D, MHC-I (blue) and Shank (red) also show colocalization in the cell bodies (purple) and alternating punctate distribution in axons. E, Ly49 (green) and synapsin-I (red) show colocalization (yellow) in cell bodies and in neurites. F, Ly49 (green) and Shank (red) show co localization (yellow) in cell bodies and alternating punctate distribution in axons. G, Cy3-cytidine 5'-triphosphate-labeled specific Ly49a probe was used to reveal its mRNA expression in adult mouse brain by in situ hybridization (see side bar next to H for intensities in pseudocolor.) Ly49a was expressed in the cerebral sensory cortex (VI, primary visual cortex; V2L, secondary visual cortex; A1, primary auditory cortex; AUD, secondary visual cortex), the hippocampus (CA1 Py, CA1 pyramidal cell layer; CA1 Or, CA1 oriens layer; CA3 Py, CA1 pyramidal cell layer; DG, dentate gyrus) and some of the pathways connecting the cortex and the hippocampus (RSG, retrosplenial cortex; PrS, presubiculum; S, subiculum). In the diencephalon expression was observed in areas containing en passent (scp and cp) or terminating (DpG) cerebellar axons, and also axons from other origins. H, Ly49a mRNA expression in the cerebellum was high in the Purkinje cell layer and moderate in the molecular and granule cell layer.

Expression of Ly49 mRNA in mouse brain was verified by in situ hybridization (because B6 mice encode numerous Ly49 genes that exhibit 79–95% identity with the probe, we cannot be certain of its hybridization partner). Ly49 mRNA was detected the cerebral cortex, hippocampus, hypothalamus (Fig. 1G), and cerebellum (Fig. 1H).

The functional significance of neuronal MHC-I expression was revealed by incubating cultures with MHC-I-specific Abs for 1, 5, or 13 days. Five-day treatment with anti-K^b mAb increased neurite growth by 3-fold, whereas anti-D^b increased neurite growth by 1.5-fold (Figs. 2 and 3A). Treatment with anti-K^b and D^b together increased the 5-day neurite growth by 2-fold and was lethal in longer treatments. Similarly, 5-day incubation with D7 or F9 Fabs increased neurite growth by 2-fold (not shown). Because the Fabs are synthesized as monovalent Ab fragments, Ab-mediated cross-linking of MHC-I is probably not required for their neuritogenic activity. Control experiments demonstrate the specificity of the effects in three different ways. First, anti-H-2^b specific Abs had no effect on BALB/c neurites, demonstrating that their activity is based on binding their target epitopes on class I molecules and not other effects. Second, a mAb specific for a viral protein did not affect B6 neurons, demonstrating that Ab alone does not affect B6 neurites. Third, anti-Thy-1 mAb did not affect B6 neurites despite the abundant expression of Thy-1 on neuron surfaces, demonstrating that simple Ab binding to neurons does not affect neurite growth (Fig. 3B).

View larger version (113K): [in this window] [in a new window]   FIGURE 2. Anti-MHC I induction of neurite branching. Montages (4 x 4) of neurite branching in 5-day-old neurons incubated with no Ab (A) or Abs specific for Db (B) or Kb (C) as revealed by GAP43 staining. A, Montage (4 x 4) of normal neuronal culture. B and C, Incubation with either H-2Db (B) or H-2Kb (C) Abs induced extensive neurites growth. D, E, and F show magnification of the frames marked by white triangles in A, B, or C, respectively.

View larger version (26K): [in this window] [in a new window]   FIGURE 3. Effects of anti-MHC or Ly49 Abs on neurite branching and neuron survival. Abs of indicated specificity were incubated at the indicated concentration with neurons from B6 (A and C–F) or BALB/c mice (B). Please note that because our treatment had also affected cell survival (D–F), branching was normalized for cell number.

Consistent with these effects, synapsin expression of cultured neurons was modulated in opposite directions by treatment with anti-MHC-I vs anti-Ly49 Abs. Although anti-MHC-I drastically diminished the number of synapsin-I-positive synapses (Fig. 4, A and B) (despite the increased neurite growth), anti-Ly49 dramatically increased the number and size of the synapsin-I positive puncta (Fig. 4, C, G, and H). Anti-Ly49 also increased synapsin-I stain throughout growth cones (Fig. 4, E and F), whereas normal growth cones showed more constricted synapsin-I stain (Fig. 4D). None of the Abs affected Shank distribution.

View larger version (53K): [in this window] [in a new window]   FIGURE 4. Effects of anti-MHC or Ly49 Abs on neuronal architecture. Synapsin-I was located in 5-day (A–F) or 13-day (G and H) neuronal cultures (all images obtained with x63 objective). A and G, Untreated neurons. B, Incubation with anti-Kb (4 µg/ml) Ab. C and H, Incubation with anti-Ly49 (1 µg/ml) Ab. D, Growth cone in untreated neurons. E and F, Growth cone of neurons incubated with Ly49G2.

View larger version (36K): [in this window] [in a new window]   FIGURE 5. Model for MHC-I/NK receptor signaling in neurons. In neurons, MHC-I/NK interactions initiate synapse formation and signal for assembly of synaptic proteins such as synapsin-I, which in turn, result in end point formation and increase neuronal viability. Lack of these interactions result in the opposite effects.

Our findings strongly suggest that the mouse nervous system adopts the immunological MHC-I Ly49A receptor system for cell-cell recognition by growing neuronal networks. The expression of Ly49 mRNA in adult brains in a region-specific manner suggests that MHC I-Ly49 interaction also functions in the mature brain. We speculate that this system is tightly controlled by the nervous system and is up-regulated during periods of plastic changes that require new synaptic connections. Given the extreme polymorphism of MHC-I genes, we predict that the MHC genotype will influence neuronal development and function. Why use MHC-I in this manner? Because class I molecules preferentially display peptides derived from newly synthesized proteins (18), they could possibly function as a "translatometers" that enable other cells to accurately monitor translational activity. This information may be very useful for neurons in particular, because translation in neurons is independently regulated at individual synapses and is intimately related to synaptic function. Because humans and other mammals lack Ly49, it is an open question as to whether MHC I plays a similar role in neuronal development and function in other species and, if so, whether NK-associated receptors or other class I-interacting gene products are used for synaptic signaling. Finally, the broadest implication of our findings is to raise the possible involvement of MHC-I/NK receptors in intercellular communication in other "nonimmune" organs and tissues.

	Acknowledgments

 
We thank Elizabeth Waffarn for outstanding technical assistance, Dr. Wayne Yokoyama for LY49A specific cDNA and Dr. Michael Edidin for helpful suggestions.

	Disclosures

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The authors have no financial conflict of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Address correspondence and reprint requests to Dr. Ofer Zohar, Blanchette Rockefeller Neurosciences Institute, Johns Hopkins University Montgomery County Campus, 9601 Medical Center Drive, Rockville, MD 20850. E-mail address: zohar{at}brni-jhu.org

² Abbreviations used in this paper: MHC-I, MHC class I; B6, C57BL/6J.

Received for publication November 30, 2007. Accepted for publication March 12, 2008.

	References

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