Abstract
For a comprehensive understanding of brain function, compiling data from a range of experiments is necessary. Digital brain atlases provide useful reference systems at the interface of neuroanatomy, neurophysiology, behavioral biology and neuroinformatics. Insect brains are particularly useful because they constitute complete three-dimensional references for the integration of morphological and functional data. Image acquisition is favored by small sized brains permitting whole brain scans using confocal microscopy. Insect brain atlases thus serve different purposes, e.g. quantitative volume analyses of brain neuropils for studying closely related species, developmental processes and neuronal plasticity; documenting and storing the Gestalt and spatial relations of neurons, neural networks and neuropils; structuring large amounts of anatomical and physiological data, thus providing a repository for data sharing among researchers. This chapter focuses on the spatial relations of neurons in the honey bee brain using the Honey bee Standard Brain (HSB). The integration of neurons into the HSB requires standardized image processing, computer algorithms and protocols that aid reconstruction and visualization. A statistical shape model has been developed in order to facilitate the segmentation process. Examples from the olfactory and mechanosensory pathways in the bee brain and the organization of the mushroom bodies (MBs) are used to illustrate the implementation and strength of the HSB. An outline will be given for the use of the brain atlas to link semantic information (e.g. from physiology, biochemistry, genetics) and neuronal morphology.
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Abbreviations
- GABA:
-
Gamma-aminobutyric acid (neurotransmitter)
- HSB:
-
Honey bee Standard Brain
- ISA:
-
Iterative Shape Averaging
- SSM:
-
Statistical shape model
- VIB:
-
Virtual insect brain
References
Abel R, Rybak J, Menzel R (2001) Structure and response patterns of olfactory interneurons in the honeybee, Apis mellifera. J Comp Neurol 437(3):363–383
Ai H (2010) Vibration-processing interneurons in the honeybee brain. Front Syst Neurosci 3(19):1–10
Ai H, Rybak J, Menzel R, Itoh T (2009) Response characteristics of vibration-sensitive interneurons related to Johnston’s organ in the honeybee, Apis mellifera. J Comp Neurol 515(2):145–160
Bertrand L, Nissanov J (2008) The neuroterrain 3D mouse brain atlas. Front Neuroinform 2(3):1–8
Boline J, Lee E-F, Toga AW (2008) Digital atlases as a framework for data sharing. Front Neurosci 2(1):100–6
Brandt R, Rohlfing T, Rybak J, Krofczik S, Maye A et al (2005) Three-dimensional average-shape atlas of the honeybee brain and its applications. J Comp Neurol 492(1):1–19
Cardona A, Saalfeld S, Preibisch S, Schmid B, Cheng A et al (2010) An integrated micro- and macroarchitectural analysis of the Drosophila brain by computer-assisted serial section electron microscopy. PLoS Biol 8(10):1–17
el Jundi B, Heinze S, Lenschow C, Kurylas A, Rohlfing T et al (2010) The locust standard brain: a 3D standard of the central complex as a platform for neural network analysis. Front Syst Neurosci 3(21):1–15
el Jundi B, Huetteroth W, Kurylas AE, Schachtner J (2009) Anisometric brain dimorphism revisited: implementation of a volumetric 3D standard brain in Manduca sexta. J Comp Neurol 517(2):210–225
Galizia CG, McIlwrath SL, Menzel R (1999) A digital three-dimensional atlas of the honeybee antennal lobe based on optical sections acquired by confocal microscopy. Cell Tissue Res 295(3):383–394
Galizia CG, Rössler W (2010) Parallel olfactory systems in insects: anatomy and function. Annu Rev Entomol 55(1):399–420
Ganeshina O, Menzel R (2001) GABA-immunoreactive neurons in the mushroom bodies of the honeybee: an electron microscopic study. J Comp Neurol 437(3):335–349
Grünewald B (1999) Morphology of feedback neurons in the mushroom body of the honeybee, Apis mellifera. J Comp Neurol 404(1):114–126
Ito K (2010) Technical and organizational considerations for the long-term maintenance and development of the digital brain atlases and web-based databases. Front Syst Neurosci 4(26):1–15
Jenett A, Schindelin J, Heisenberg M (2006) The Virtual Insect Brain protocol: creating and comparing standardized neuroanatomy. BMC Bioinforma 7(1):544
Jones AR, Overly CC, Sunkin SM (2009) The allen brain atlas: 5 years and beyond. Nat Rev Neurosci 10(11):821–828
Joshi SH, Van Horn J, Toga AW (2009) Interactive exploration of neuroanatomical meta-spaces. Front in Neuroinform 3(38):1–10
Kenyon CF (1896) The brain of the bee. A preliminary contribution to the morphology of the nervous system of the arthropoda. J Comp Neurol 6:133–210
Kirschner S, Kleineidam CJ, Zube C, Rybak J, Grünewald B et al (2006) Dual olfactory pathway in the honeybee, Apis mellifera. J Comp Neurol 499(6):933–952
Krofczik S, Menzel R, Nawrot MP (2009) Rapid odor processing in the honeybee antennal lobe network. Front Comput Neurosci 2(9):1–13
Kurylas AE, Rohlfing T, Krofczik S, Jenett A, Homberg U (2008) Standardized atlas of the brain of the desert locust, Schistocerca gregaria. Cell Tissue Res 333(1):125–145
Kuß A, Hege H-C, Krofczik S, Börner J (2007) Pipeline for the creation of surface-based averaged brain atlases. Proceedings of WSCG 2007 - the 15-th International Conference in Central Europe on Computer Graphics, Visualization and Computer Vision. Plzen, Czech Republic. 15:17–24.
Kuß A, Prohaska S, Meyer B, Rybak J, Hege H-C (2008) Ontology-based visualization of hierarchical neuroanatomical structures. In: Botha CP et al (eds) Proc Visual Computing for Biomedicine, Delft, pp 177–184
Kvello P, Lofaldli BB, Rybak J, Menzel R, Mustaparta H (2009) Digital, three-dimensional average shaped atlas of the Heliothis virescens brain with integrated gustatory and olfactory neurons. Front Syst Neurosci 3(14):1–14
Lamecker H, Lange T, Seebaß M, Eulenstein S, Westerhoff M et al (2003) Automatic segmentation of the liver for preoperative planning of resections. Ios Press, Newport Beach. 171–173
Larson SD, Martone ME (2009) Ontologies for neuroscience: what are they and what are they good for? Front Neurosci 3:1, 60–67
Maronde U (1991) Common projection areas of antennal and visual pathways in the honeybee brain, Apis mellifera. J Comp Neurol 309(3):328–340
Maye A, Wenckebach T, Hege H (2006) Visualization, reconstruction, and integration of neuronal structures in digital brain atlases. Int J Neurosci 116:431–459
Menzel R (2001) Searching for the memory trace in a mini-brain, the honeybee. Learn Mem 8(2):53–62
Menzel R (2009) Conditioning: simple neural circuits in the honeybee. In: Squire LR (ed) Encyclopedia of neuroscience, vol 3. Academic, Oxford, pp 43–47
Mobbs PG (1982) The brain of the honeybee Apis mellifera. I. The connections and spatial organization of the mushroom bodies. Phil Trans R Soc Lond B 298:309–354
Müller D, Abel R, Brandt R, Zockler M, Menzel R (2002) Differential parallel processing of olfactory information in the honeybee, Apis mellifera L. J Comp Physiol A 188(5):359–370
Münch D (2008) Intrazelluläre Färbungen und 3D Strukturanalyse von olfaktorischen Projektionsneuronen im Bienengehirn. MSc, FU Berlin, Berlin
Namiki S, Haupt SS, Kazawa T, Takashima A, Ikeno H et al (2009) Reconstruction of virtual neural circuits in an insect brain. Front Neurosci 3(2):206–213
Neubert K (2007) Model-based autosegmentation of brain structures in the honeybee, Apis mellifera. FU Berlin, Berlin
Okada R, Rybak J, Manz G, Menzel R (2007) Learning-related plasticity in PE1 and other mushroom body-extrinsic neurons in the honeybee brain. J Neurosci 27(43):11736–11747
Peng H (2008) Bioimage informatics: a new area of engineering biology. Bioinformatics 24(17):1827–1836
Rein K, Zockler M, Mader M, Grubel C, Heisenberg M (2002) The Drosophila standard brain. Curr Biol 12:227–231
Rohlfing T, Brandt R, Maurer Jr. CR, Menzel R (2001) Bee brains, B-splines and computational democracy: generating an average shape atlas. In: Proceedings of the IEEE workshop on mathematical methods in Biomedical Image Analysis, Kauai, Hawaii. 187–194
Rybak J (1994) Die strukturelle Organisation der Pilzkörper und synaptische Konnektivität protocerebraler Interneuronen im Gehirn der Honigbiene, Apis mellifera: eine licht- und elektronenmikroskopische Studie. Dissertation, FU Berlin, Berlin
Rybak J, Kuss A, Lamecker H, Zachow S, Hege HC et al (2010) The digital bee brain: integrating and managing neurons in a common 3D reference system. Front Syst Neurosci 4(30):1–14
Rybak J, Menzel R (1993) Anatomy of the mushroom bodies in the honey bee brain: the neuronal connections of the alpha-lobe. J Comp Neurol 334(3):444–465
Rybak J, Menzel R (2010) Mushroom body of the honeybee. In: Shepherd GM, Grillner S (eds) Handbook of brain microcircuits. Oxford University Press, New York, pp 433–440
Schäfer S, Bicker G (1986) Distribution of GABA-like immunoreactivity in the brain of the honeybee. J Comp Neurol 246(3):287–300
Strausfeld NJ (1976) Atlas of an insect brain. Springer, Berlin/Heidelberg/New York
Strausfeld NJ (2002) Organization of the honey bee mushroom body: representation of the calyx within the vertical and gamma lobes. J Comp Neurol 450(1):4–33
Talairach J, Tournoux P (1988) Co-planar stereotaxic atlas of the human brain: 3-dimensional proportional system – an approach to cerebral imaging. Thieme Medical Publishers, New York
Toga AW, Mazziotta JC (2002) Brain mapping: the methods, 2nd edn. Academic Press, San Diego
Toga AW, Thompson PM (2001) Maps of the brain. Anat Rec 265(2):37–53
Vowles DM (1955) The structure and connections of the corpora pedunculata in bees and ants. Q J Microsc Sci 96:239–255
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Rybak, J. (2012). The Digital Honey Bee Brain Atlas. In: Galizia, C., Eisenhardt, D., Giurfa, M. (eds) Honeybee Neurobiology and Behavior. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-2099-2_11
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