Cajal–Retzius cell explained

Cajal-Retzius Cell

Cajal–Retzius cells (CR cells) (also known as Horizontal cells of Cajal) are a heterogeneous population of morphologically and molecularly distinct reelin-producing cell types in the marginal zone/layer I of the developing cerebral cortex and in the immature hippocampus of different species and at different times during embryogenesis and postnatal life.

These cells were discovered by two scientists, Santiago Ramón y Cajal and Gustaf Retzius, at two different times and in different species. They are originated in the developing brain in multiple sites within the neocortex and hippocampus. From there, Cajal–Retzius (CR) cells migrate through the marginal zone, originating the layer I of the cortex.

As these cells are involved in the correct organization of the developing brain, there are several studies implicating CR cells in neurodevelopmental disorders, especially schizophrenia, bipolar disorder, autism, lissencephaly and temporal lobe epilepsy.

Development

In 1971 it was described that it was very difficult to find a CR cell in the adult cortex, because of the constant number of these cells and the fact that as the brain grows, the distance between these cells increases, required the observation of a great number of preparations to find one of these cells.In mice, CR cells are generated very early in the development, appearing between 10,5 and 12,5 embryonic days.

Cajal–Retzius cells were described to migrate tangentially in the marginal zone, a superficial layer of the preplate in the cortical neuroepithelium,[1] [2] According to some studies, this migration depends on the site where the cell was generated, showing a link between the origin, the migration and the destination of the cell.[3]

Studies have shown that Cajal–Retzius cells have different origins, both in the neocortex and in the hippocampus. In the neocortex they originate in the local pallium ventricular zone, the pallial-subpallial border of the ventral pallium, a region at the septum, the cortical hem [4] and the retrobulbar ventricular zone.[5]

In 2006 it was demonstrated that in mouse cells, the meninges control the migration of the CR cells in the cortical hem.[6] Subpopulations of these neurons from the septum and pallial-subpallial border express the homeodomain transcription factor Dbx1 and migrate to the medial, dorsolateral and piriform cortex and though genetically different from the other subpopulations (Dbx1 negative), all have the same morphological and electrophysiological properties, despite the different origins of CR cells.[7]

Function

Cajal–Retzius cells are involved in the organization of the developing brain. In 1998, immature neurons from the pyramidal neocortex and other regions of the immature brain showed membrane depolarizations of CR cells caused by GABA-A and glycine receptor activation.[8] In 1994, a subpopulation of CR cells was shown to be GABAergic (using GABA as a transmitter).[9]

In 2003, CR cells in rodents and primates were shown to be glutamatergic (using glutamate as a transmitter).[10] Immunohistochemical studies (detecting antigens by exploiting the principle of antibodies binding specifically to antigens in biological tissues) showed that CR cells expressed GABA-A and GABA-B receptors, ionotropic and metabotropic glutamate receptors, vesicular glutamate transporters,[11] and a number of different calcium-binding proteins, such as calbindin, calretinin and parvalbumin. CR cells express several genes important in corticogenesis, such as reelin (RELN), LIS1, EMX2, and DS-CAM. CR cells selectively express p73, a member of the p53 family involved in cell death and survival.

CR cells receive an early serotonergic input, which in mice forms synaptic contacts.[12]

In 2001, CR cells in the marginal zone were found to have electrophysiological fingerprints. Whole-cell patch-clamp studies (the laboratory technique in electrophysiology allowing the study of single or multiple ion channels in cells) showed that CRN injected by a suprathreshold depolarizing current pulse express a repetitive firing mode and cells injected by a hyperpolarizing current pulse, express a hyperpolarization-activated inward current (H-current).[13]

Using chloride-containing patch-clamp electrodes in 2006, spontaneous postsynaptic currents (PSCs) were recorded in about 30% of the CR cells in P0-P2 rat cerebral cortex. These spontaneous postsynaptic currents decreased to about 10% at P4, indicating that CR cells became functionally disconnected during further development.[14] these spontaneous postsynaptic currents were reversibly blocked by bicuculline, a light-sensitive competitive antagonist of GABA-A receptors, suggesting activation of GABA-A receptors in these spontaneous postsynaptic currents. Moreover, the frequency and amplitude of these spontaneous postsynaptic currents was not influenced by tetrodotoxin, which inhibits the firing of action potentials in nerves, indicating that these spontaneous postsynaptic currents are independent on presynaptic action potentials.[14]

Brain development

CR cells secrete the extracellular matrix protein reelin, which is critically involved in the control of radial neuronal migration through a signaling pathway, including the very low density lipoprotein receptor (VLDLR), the apolipoprotein E receptor type 2 (ApoER2), and the cytoplasmic adapter protein disabled 1 (Dab1). In early cortical development in mice, mutations of Dab1, VLDLR, and ApoER2, generate similar abnormal phenotypes, called reeler-like phenotype. It performs several abnormal processes in brain development, such as forming an outside to inside gradient, forming cells in an oblique orientation. Therefore, CR cells control two processes: detachment from radial glia and somal translocation in the formation of cortical layers. In addition, the reeler type also manifests a poor organization of the Purkinje cell plate(PP) and the inferior olivary complex(IOC).

Clinical significance

Problems in migration, especially those that arise from the lack of reelin production, may influence brain development and lead to disorders in brain's normal functioning. In the 1950s, the reeler mutant mouse was described by Falconer as a naturally occurring mutant. It exhibits some behavioral abnormalities, such as ataxia, tremor and hypotonia, which were discovered to be related to problems in neuronal migration and consequently, cytoarchitecture in the cerebellum, hippocampus and cerebral cortex.[15] [16]

It was found later that the mutation causing these disorders was located in the RELN gene which codes for reelin, a glycoprotein secreted by Cajal–Retzius cells in the developing brain. This protein seems to act as a stop signal for migrating neurons, controlling the positioning and orientation of neurons in their layers, according to the inside-out pattern of development. When the mutation occurs, reelin expression is reduced and this signal isn't as strong, therefore, migration of the first neurons in the brain is not done correctly.[15] [17] The reeler mutant has been used, because of its characteristics, as a model for the study of neuropsychiatric disorders.[17]

History

In 1891 Santiago Ramón y Cajal described slender horizontal bipolar cells he had found in an histological preparation of the developing marginal zone of lagomorphs.[24] These cells were then considered by Gustaf Retzius as homologous to the ones he had found in the marginal zone of human fetuses around mid-gestation in 1893 and 1894. He described those cells as having large, horizontal, sometimes vertically orientated somata located at some distance from the pia.[25] [26]

Later on in 1899, Cajal drew the neurons in layer I of the human fetus at term and newborn.[27] The cells laid closer to the pia and displayed smaller, often triangular or pyriform somata, and less complex processes that lacked the ascending branchlets and had a more superficial location than the cells Retzius previously described,[28] [29] [30] The cells' different morphologies and the fact that Cajal and Retzius used different species at different developmental periods led to discussion about the definition of Cajal–Retzius cells.[31] [32] [33] [34] [35] [36] In fact immunohistochemical studies performed at advanced developmental stages in human and macaque cortex visualize cells more similar to the cells Cajal described.[33] [37]

In contrast, studies from 1994 of the human mid-gestation period describe cells closer to the Retzius type.[38]

The early descriptions by Cajal and Retzius referred to the neocortex, but since 1994 similar cells have been found in the marginal zone of the hippocampus.[36] [38] [39] [40]

Various studies then proved the Cajal–Retzius cells as being responsible for the production of reelin,[40] [41] [42]

In 1999, Meyer loosely defined the Cajal–Retzius cells as the family of Reln-immunoreactive neurons in the marginal zone of the hippocampus,[43] as so to settle a difference between the pioneer neurons, Reln-negative preplate derivatives that settle in the same area and project to the subcortical area that he had already described in 1998.[44] He also described simpler cells with simpler morphologies in the marginal zone of rodents.[43]

In 2005, the discovery of heterogeneous transcription factors and new sites of origin suggested that there were distinct subpopulations of Cajal–Retzius cells in different territories of the developing cortex.[45]

As of 2017, a clear classification scheme has not been established.

See also

List of distinct cell types in the adult human body

Notes and References

  1. Marin-Padilla M . Early prenatal ontogenesis of the cerebral cortex (neocortex) of the cat (Felis domestica). A Golgi study. I. The primordial neocortical organization . Zeitschrift für Anatomie und Entwicklungsgeschichte . 134 . 2 . 117–45 . 1971 . 4932608 . 10.1007/BF00519296.
  2. Marin-Padilla M . Prenatal ontogenetic history of the principal neurons of the neocortex of the cat (Felis domestica). A Golgi study. II. Developmental differences and their significances . Zeitschrift für Anatomie und Entwicklungsgeschichte . 136 . 2 . 125–42 . 1972 . 5042754 . 10.1007/BF00519174.
  3. García-Moreno F, López-Mascaraque L, De Carlos JA . Origins and migratory routes of murine Cajal-Retzius cells . The Journal of Comparative Neurology . 500 . 3 . 419–32 . January 2007 . 17120279 . 10.1002/cne.21128. 10261/62337 . free .
  4. Takiguchi-Hayashi K, Sekiguchi M, Ashigaki S . Generation of reelin-positive marginal zone cells from the caudomedial wall of telencephalic vesicles . The Journal of Neuroscience . 24 . 9 . 2286–95 . March 2004 . 14999079 . 6730420 . 10.1523/JNEUROSCI.4671-03.2004. etal. free .
  5. Lavdas AA, Grigoriou M, Pachnis V, Parnavelas JG . The medial ganglionic eminence gives rise to a population of early neurons in the developing cerebral cortex . The Journal of Neuroscience . 19 . 18 . 7881–8 . September 1999 . 10.1523/JNEUROSCI.19-18-07881.1999 . 10479690 . 6782477 .
  6. Borrell V, Marín O . Meninges control tangential migration of hem-derived Cajal-Retzius cells via CXCL12/CXCR4 signaling . Nature Neuroscience . 9 . 10 . 1284–93 . October 2006 . 16964252 . 10.1038/nn1764.
  7. Sava BA, Dávid CS, Teissier A . Electrophysiological and morphological properties of Cajal-Retzius cells with different ontogenetic origins . Neuroscience . 167 . 3 . 724–34 . May 2010 . 20188149 . 10.1016/j.neuroscience.2010.02.043. etal.
  8. Mienville JM . Persistent depolarizing action of GABA in rat Cajal-Retzius cells . The Journal of Physiology . 512 . Pt 3 . 809–17 . November 1998 . 9769423 . 2231241 . 10.1111/j.1469-7793.1998.809bd.x.
  9. Imamoto K, Karasawa N, Isomura G, Nagatsu I . Cajal-Retzius neurons identified by GABA immunohistochemistry in layer I of the rat cerebral cortex . Neuroscience Research . 20 . 1 . 101–5 . July 1994 . 7984336 . 10.1016/0168-0102(94)90027-2.
  10. Hevner RF, Neogi T, Englund C, Daza RA, Fink A . Cajal-Retzius cells in the mouse: transcription factors, neurotransmitters, and birthdays suggest a pallial origin . Brain Research. Developmental Brain Research . 141 . 1–2 . 39–53 . March 2003 . 12644247 . 10.1016/S0165-3806(02)00641-7.
  11. Ina A, Sugiyama M, Konno J . Cajal-Retzius cells and subplate neurons differentially express vesicular glutamate transporters 1 and 2 during development of mouse cortex . The European Journal of Neuroscience . 26 . 3 . 615–23 . August 2007 . 17651422 . 10.1111/j.1460-9568.2007.05703.x. etal.
  12. Janusonis S, Gluncic V, Rakic P . Early serotonergic projections to Cajal-Retzius cells: relevance for cortical development . The Journal of Neuroscience . 24 . 7 . 1652–9 . February 2004 . 14973240 . 6730467. 10.1523/JNEUROSCI.4651-03.2004. free .
  13. Kilb W, Luhmann HJ . Spontaneous GABAergic postsynaptic currents in Cajal-Retzius cells in neonatal rat cerebral cortex . The European Journal of Neuroscience . 13 . 7 . 1387–90 . April 2001 . 11298799 . 10.1046/j.0953-816x.2001.01514.x.
  14. Kirmse K, Kirischuk S . Ambient GABA constrains the strength of GABAergic synapses at Cajal-Retzius cells in the developing visual cortex . The Journal of Neuroscience . 26 . 16 . 4216–27 . April 2006 . 16624942 . 6674013 . 10.1523/JNEUROSCI.0589-06.2006. free .
  15. Badea A, Nicholls PJ, Johnson GA, Wetsel WC . Neuroanatomical phenotypes in the reeler mouse . NeuroImage . 34 . 4 . 1363–74 . February 2007 . 17185001 . 1945208 . 10.1016/j.neuroimage.2006.09.053.
  16. Katsuyama Y, Terashima T . Developmental anatomy of reeler mutant mouse . Development, Growth & Differentiation . 51 . 3 . 271–86 . April 2009 . 19379278 . 10.1111/j.1440-169X.2009.01102.x. free .
  17. Folsom TD, Fatemi SH . The involvement of Reelin in neurodevelopmental disorders . Neuropharmacology . 68 . 122–35 . May 2013 . 22981949 . 3632377 . 10.1016/j.neuropharm.2012.08.015.
  18. Baloyannis SJ . Morphological and morphometric alterations of Cajal-Retzius cells in early cases of Alzheimer's disease: a Golgi and electron microscope study . The International Journal of Neuroscience . 115 . 7 . 965–80 . July 2005 . 16051543 . 10.1080/00207450590901396.
  19. Lakatosova S, Ostatnikova D . Reelin and its complex involvement in brain development and function . The International Journal of Biochemistry & Cell Biology . 44 . 9 . 1501–4 . September 2012 . 22705982 . 10.1016/j.biocel.2012.06.002.
  20. Fatemi SH, Snow AV, Stary JM . Reelin signaling is impaired in autism . Biological Psychiatry . 57 . 7 . 777–87 . April 2005 . 15820235 . 10.1016/j.biopsych.2004.12.018. etal.
  21. Wynshaw-Boris A . Lissencephaly and LIS1: insights into the molecular mechanisms of neuronal migration and development . Clinical Genetics . 72 . 4 . 296–304 . October 2007 . 17850624 . 10.1111/j.1399-0004.2007.00888.x.
  22. Kato M, Dobyns WB . Lissencephaly and the molecular basis of neuronal migration . Human Molecular Genetics . 12 . Suppl 1 . R89–96 . April 2003 . 12668601 . 10.1093/hmg/ddg086. free .
  23. Blümcke I, Thom M, Wiestler OD . Ammon's horn sclerosis: a maldevelopmental disorder associated with temporal lobe epilepsy . Brain Pathology . 12 . 2 . 199–211 . April 2002 . 11958375 . 10.1111/j.1750-3639.2002.tb00436.x. 8095862 .
  24. Santiago . Ramón y Cajal . Sur la structure de l'ecorce cérébrale de quelques mammifères . On the structure of the cerebral cortex in some mammals . es . La Cellule . 7 . 123–76 . 1891 .
  25. Retzius G . Die Cajal'schen Zellen der Grosshirnrinde beim Menschen und bei Säugetieren . The Cajal'schen cells of the cerebral cortex in humans and mammals . de . Biologische Untersuchungen . 5 . 1–8 . 1893.
  26. Retzius G . Weitere Beiträge zur Kenntniss der Cajal'schen Zellen der Grosshirnrinde des Menschen . Further contributions to the knowledge of the Cajal'schen cells of the cerebral cortex of man . de . Biologische Untersuchungen . 6 . 29–36 . 1894.
  27. Ramón y Cajal S . Estudios sobre la corteza cerebral humana. I. Corteza visual . Studies on the human cerebral cortex. I. Visual Cortex . es . Revista Trimestral Micrográfica . 4 . 1–63 . 1899.
  28. Tissir F, Goffinet AM . Reelin and brain development . Nature Reviews. Neuroscience . 4 . 6 . 496–505 . June 2003 . 12778121 . 10.1038/nrn1113.
  29. Ramón y Cajal S . Estudios sobre la corteza cerebral humana. II. Estructura de la corteza motriz del hombre y mamíferos superiores . Studies on the human cerebral cortex. II. Structure of the motor cortex of man and higher mammals . Revista Trimestral Micrográfica . 4 . 117–200 . 1899.
  30. Book: Ramón y Cajal S . Histologie du système nerveux de l'homme et des vertébrés . Histology of the nervous system of man and vertebrates . 2 . Paris . Maloine . 1911.
  31. Duckett S, Pearse AG . The cells of Cajal-Retzius in the developing human brain . Journal of Anatomy . 102 . Pt 2 . 183–7 . January 1968 . 4296164 . 1231310.
  32. König N . Retzius-Cajal or Cajal-Retzius cells? . Neuroscience Letters . 9 . 4 . 361–3 . October 1978 . 19605246 . 10.1016/0304-3940(78)90209-4.
  33. Huntley GW, Jones EG . Cajal-Retzius neurons in developing monkey neocortex show immunoreactivity for calcium binding proteins . Journal of Neurocytology . 19 . 2 . 200–12 . April 1990 . 2358829 . 10.1007/BF01217298.
  34. Marin-Padilla M . Dual origin of the mammalian neocortex and evolution of the cortical plate . Anatomy and Embryology . 152 . 2 . 109–26 . February 1978 . 637312 . 10.1007/BF00315920.
  35. Marín-Padilla M . Three-dimensional structural organization of layer I of the human cerebral cortex: a Golgi study . The Journal of Comparative Neurology . 299 . 1 . 89–105 . September 1990 . 2212113 . 10.1002/cne.902990107.
  36. Supèr H, Soriano E, Uylings HB . The functions of the preplate in development and evolution of the neocortex and hippocampus . Brain Research. Brain Research Reviews . 27 . 1 . 40–64 . June 1998 . 9639671 . 10.1016/S0165-0173(98)00005-8.
  37. Uylings HB, Delalle I . Morphology of neuropeptide Y-immunoreactive neurons and fibers in human prefrontal cortex during prenatal and postnatal development . The Journal of Comparative Neurology . 379 . 4 . 523–40 . March 1997 . 9067841 . 10.1002/(SICI)1096-9861(19970324)379:4<523::AID-CNE5>3.0.CO;2-4.
  38. Soriano E, Del Río JA, Martínez A, Supèr H . Organization of the embryonic and early postnatal murine hippocampus. I. Immunocytochemical characterization of neuronal populations in the subplate and marginal zone . The Journal of Comparative Neurology . 342 . 4 . 571–95 . April 1994 . 7913715 . 10.1002/cne.903420406.
  39. Drakew A, Frotscher M, Deller T, Ogawa M, Heimrich B . Developmental distribution of a reeler gene-related antigen in the rat hippocampal formation visualized by CR-50 immunocytochemistry . Neuroscience . 82 . 4 . 1079–86 . February 1998 . 9466431 . 10.1016/S0306-4522(97)00326-6.
  40. Alcántara S, Ruiz M, D'Arcangelo G . Regional and cellular patterns of reelin mRNA expression in the forebrain of the developing and adult mouse . The Journal of Neuroscience . 18 . 19 . 7779–99 . October 1998 . 9742148 . etal . 10.1523/JNEUROSCI.18-19-07779.1998 . 6792998.
  41. D'Arcangelo G, Nakajima K, Miyata T, Ogawa M, Mikoshiba K, Curran T . Reelin is a secreted glycoprotein recognized by the CR-50 monoclonal antibody . The Journal of Neuroscience . 17 . 1 . 23–31 . January 1997 . 10.1523/JNEUROSCI.17-01-00023.1997 . 8987733 . 6793694 .
  42. Ogawa M, Miyata T, Nakajima K . The reeler gene-associated antigen on Cajal-Retzius neurons is a crucial molecule for laminar organization of cortical neurons . Neuron . 14 . 5 . 899–912 . May 1995 . 7748558 . 10.1016/0896-6273(95)90329-1. etal. free .
  43. Meyer G, Goffinet AM, Fairén A . What is a Cajal-Retzius cell? A reassessment of a classical cell type based on recent observations in the developing neocortex . Cerebral Cortex . 9 . 8 . 765–75 . December 1999 . 10600995 . 10.1093/cercor/9.8.765. free .
  44. Meyer G, Soria JM, Martínez-Galán JR, Martín-Clemente B, Fairén A . Different origins and developmental histories of transient neurons in the marginal zone of the fetal and neonatal rat cortex . The Journal of Comparative Neurology . 397 . 4 . 493–518 . August 1998 . 9699912 . 10.1002/(SICI)1096-9861(19980810)397:4<493::AID-CNE4>3.0.CO;2-X.
  45. Bielle F, Griveau A, Narboux-Nême N . Multiple origins of Cajal-Retzius cells at the borders of the developing pallium . Nature Neuroscience . 8 . 8 . 1002–12 . August 2005 . 16041369 . 10.1038/nn1511. etal.