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https://en.wikipedia.org/wiki/Reelin
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Reelin, encoded by the RELN gene, is a large secreted extracellular matrix glycoprotein that helps regulate processes of neuronal migration and positioning in the developing brain by controlling cell–cell interactions. Besides this important role in early development, reelin continues to work in the adult brain. It modulates synaptic plasticity by enhancing the induction and maintenance of long-term potentiation. It also stimulates dendrite and dendritic spine development and regulates the continuing migration of neuroblasts generated in adult neurogenesis sites like the subventricular and subgranular zones. It is found not only in the brain but also in the liver, thyroid gland, adrenal gland, Fallopian tube, breast and in comparatively lower levels across a range of anatomical regions.
Reelin has been suggested to be implicated in pathogenesis of
several brain diseases. The expression of the protein has been found to
be significantly lower in schizophrenia and psychotic bipolar disorder, but the cause of this observation remains uncertain, as studies show that psychotropic medication itself affects reelin expression. Moreover, epigenetic hypotheses aimed at explaining the changed levels of reelin expression are controversial. Total lack of reelin causes a form of lissencephaly. Reelin may also play a role in Alzheimer's disease, temporal lobe epilepsy and autism.
Reelin's name comes from the abnormal reeling gait of reeler mice, which were later found to have a deficiency of this brain protein and were homozygous for mutation of the RELN gene.
The primary phenotype associated with loss of reelin function is a failure of neuronal positioning throughout the developing central nervous system (CNS). The mice heterozygous for the reelin gene, while having little neuroanatomical defects, display the endophenotypic traits linked to psychotic disorders.
Discovery
Normal and
Reeler mice brain slices.
Mutant mice have provided insight into the underlying molecular mechanisms of the development of the central nervous system. Useful spontaneous mutations were first identified by scientists who were interested in motor behavior, and it proved relatively easy to screen littermates
for mice that showed difficulties moving around the cage. A number of
such mice were found and given descriptive names such as reeler, weaver,
lurcher, nervous, and staggerer.
The "reeler" mouse was described for the first time in 1951 by D.S.Falconer in Edinburgh University as a spontaneous variant arising in a colony of at least mildly inbred snowy-white bellied mice stock in 1948. Histopathological studies in the 1960s revealed that the cerebellum
of reeler mice is dramatically decreased in size while the normal
laminar organization found in several brain regions is disrupted. The 1970s brought about the discovery of cellular layer inversion in the mouse neocortex, which attracted more attention to the reeler mutation.
In 1994, a new allele of reeler was obtained by means of insertional mutagenesis. This provided the first molecular marker of the locus, permitting the RELN gene to be mapped to chromosome 7q22 and subsequently cloned and identified. Japanese scientists at Kochi Medical School successfully raised antibodies against normal brain extracts in reeler mice, later these antibodies were found to be specific monoclonal antibodies for reelin, and were termed CR-50 (Cajal-Retzius marker 50). They noted that CR-50 reacted specifically with Cajal-Retzius neurons, whose functional role was unknown until then.
The Reelin receptors, apolipoprotein E receptor 2 (ApoER2) and very-low-density lipoprotein receptor
(VLDLR), were discovered by Trommsdorff, Herz and colleagues, who
initially found that the cytosolic adaptor protein Dab1 interacts with
the cytoplasmic domain of LDL receptor family members. They then went on to show that the double knockout mice for ApoER2 and VLDLR, which both interact with Dab1, had cortical layering defects similar to those in reeler.
The downstream pathway of reelin was further clarified with the help of other mutant mice, including yotari and scrambler.
These mutants have phenotypes similar to that of reeler mice, but
without mutation in reelin. It was then demonstrated that the mouse disabled homologue 1 (Dab1)
gene is responsible for the phenotypes of these mutant mice, as Dab1
protein was absent (yotari) or only barely detectable (scrambler) in
these mutants. Targeted disruption of Dab1 also caused a phenotype similar to that of reeler. Pinpointing the DAB1 as a pivotal regulator of the reelin signaling cascade started the tedious process of deciphering its complex interactions.
There followed a series of speculative reports linking reelin's
genetic variation and interactions to schizophrenia, Alzheimer's
disease, autism and other highly complex dysfunctions. These and other
discoveries, coupled with the perspective of unraveling the evolutionary
changes that allowed for the creation of human brain, highly
intensified the research. As of 2008, some 13 years after the gene
coding the protein was discovered, hundreds of scientific articles
address the multiple aspects of its structure and functioning.
Tissue distribution and secretion
Studies show that reelin is absent from synaptic vesicles and is secreted via constitutive secretory pathway, being stored in Golgi secretory vesicles. Reelin's release rate is not regulated by depolarization, but strictly depends on its synthesis rate. This relationship is similar to that reported for the secretion of other extracellular matrix proteins.
During the brain development, reelin is secreted in the cortex and hippocampus by the so-called Cajal-Retzius cells, Cajal cells, and Retzius cells.
Reelin-expressing cells in the prenatal and early postnatal brain are
predominantly found in the marginal zone (MZ) of the cortex and in the
temporary subpial granular layer (SGL), which is manifested to the highest extent in human, and in the hippocampal stratum lacunosum-moleculare and the upper marginal layer of the dentate gyrus.
In the developing cerebellum, reelin is expressed first in the external granule cell layer (EGL), before the granule cell migration to the internal granule cell layer (IGL) takes place.
Having peaked just after the birth, the synthesis of reelin
subsequently goes down sharply, becoming more diffuse compared with the
distinctly laminar expression in the developing brain. In the adult
brain, reelin is expressed by GABA-ergic interneurons of the cortex and glutamatergic cerebellar neurons, the glutamatergic stellate cells and fan cells in the superficial entorhinal cortex that are supposed to carry a role in encoding new episodic memories,
and by the few extant Cajal-Retzius cells. Among GABAergic
interneurons, reelin seems to be detected predominantly in those
expressing calretinin and calbindin, like bitufted, horizontal, and Martinotti cells, but not parvalbumin-expressing cells, like chandelier or basket neurons. In the white matter, a minute proportion of interstitial neurons has also been found to stain positive for reelin expression.
Schema of the reelin protein
Outside the brain, reelin is found in adult mammalian blood, liver, pituitary pars intermedia, and adrenal chromaffin cells. In the liver, reelin is localized in hepatic stellate cells. The expression of reelin increases when the liver is damaged, and returns to normal following its repair.
In the eyes, reelin is secreted by retinal ganglion cells and is also found in the endothelial layer of the cornea. Just as in the liver, its expression increases after an injury has taken place.
The protein is also produced by the odontoblasts, which are cells at the margins of the dental pulp. Reelin is found here both during odontogenesis and in the mature tooth. Some authors suggest that odontoblasts play an additional role as sensory cells able to transduce pain signals to the nerve endings. According to the hypothesis, reelin participates in the process by enhancing the contact between odontoblasts and the nerve terminals.
Structure
Reelin is composed of 3461 amino acids with a relative molecular mass of 388 kDa. It also has serine protease activity. Murine RELN gene consists of 65 exons spanning approximately 450 kb. One exon, coding for only two amino acids near the protein's C-terminus, undergoes alternative splicing, but the exact functional impact of this is unknown. Two transcription initiation sites and two polyadenylation sites are identified in the gene structure.
The reelin protein starts with a signaling peptide 27 amino acids in length, followed by a region bearing similarity to F-spondin (the reeler domain),
marked as "SP" on the scheme, and by a region unique to reelin, marked
as "H". Next comes 8 repeats of 300–350 amino acids. These are called reelin repeats and have an epidermal growth factor motif at their center, dividing each repeat into two subrepeats, A (the BNR/Asp-box repeat) and B (the EGF-like domain). Despite this interruption, the two subdomains make direct contact, resulting in a compact overall structure.
The final reelin domain contains a highly basic and short
C-terminal region (CTR, marked "+") with a length of 32 amino acids.
This region is highly conserved, being 100% identical in all
investigated mammals. It was thought that CTR is necessary for reelin
secretion, because the Orleans reeler
mutation, which lacks a part of 8th repeat and the whole CTR, is unable
to secrete the misshaped protein, leading to its concentration in
cytoplasm. However, other studies have shown that the CTR is not
essential for secretion itself, but mutants lacking the CTR were much
less efficient in activating downstream signaling events.
Reelin is cleaved in vivo at two sites located after
domains 2 and 6 – approximately between repeats 2 and 3 and between
repeats 6 and 7, resulting in the production of three fragments.
This splitting does not decrease the protein's activity, as constructs
made of the predicted central fragments (repeats 3–6) bind to
lipoprotein receptors, trigger Dab1 phosphorylation and mimic functions of reelin during cortical plate development. Moreover, the processing of reelin by embryonic neurons may be necessary for proper corticogenesis.
Function
As they travel through the
rostral migratory stream, neuroblasts are held together, probably in part by
thrombospondin-1's binding to the reelin receptors
ApoER2 and
VLDLR.
As they arrive to the destination, the groups are dispersed by reelin
and cells strike out on their individual paths. A fragment of an
illustration from Lennington et al., 2003.
The primary functions of Reelin are the regulation of corticogenesis
and neuronal cell positioning in the prenatal period, but the protein
also continues to play a role in adults. Reelin is found in numerous
tissues and organs, and one could roughly subdivide its functional roles
by the time of expression and by localisation of its action.
During development
A
number of non-nervous tissues and organs express reelin during
development, with the expression sharply going down after organs have
been formed. The role of the protein here is largely unexplored, because
the knockout mice show no major pathology in these organs. Reelin's
role in the growing central nervous system has been extensively
characterized. It promotes the differentiation of progenitor cells into radial glia and affects the orientation of its fibers, which serve as the guides for the migrating neuroblasts.
The position of reelin-secreting cell layer is important, because the
fibers orient themselves in the direction of its higher concentration. For example, reelin regulates the development of layer-specific connections in hippocampus and entorhinal cortex.[
Reelin controls the direction of radial glia growth. A fragment of an
illustration from Nomura T. et al., 2008.
Reelin-expressing cells (red) on C stimulate the growth of green glial
fibers, while on B, where the red cells do not express reelin, radial
glia is more disarrayed.
Mammalian corticogenesis
is another process where reelin plays a major role. In this process the
temporary layer called preplate is split into the marginal zone on the
top and subplate below, and the space between them is populated by
neuronal layers in the inside-out pattern. Such an arrangement, where
the newly created neurons pass through the settled layers and position
themselves one step above, is a distinguishing feature of mammalian
brain, in contrast to the evolutionary older reptile cortex, in which
layers are positioned in an "outside-in" fashion. When reelin is absent,
like in the mutant reeler
mouse, the order of cortical layering becomes roughly inverted, with
younger neurons finding themselves to be unable to pass the settled
layers. Subplate neurons fail to stop and invade the upper most layer,
creating the so-called superplate in which they mix with Cajal-Retzius cells and some cells normally destined for the second layer.
Increased
reelin expression changes the morphology of migrating neurons: unlike
the round neurons with short branches (C) they assume bipolar shape (D)
and attach themselves (E) to the
radial glia fibers that are extending in the direction of reelin-expressing cells. Nomura T. et al., 2008.
There is no agreement concerning the role of reelin in the proper
positioning of cortical layers. The original hypothesis, that the
protein is a stop signal for the migrating cells, is supported by its
ability to induce the dissociation,
its role in asserting the compact granule cell layer in the
hippocampus, and by the fact that migrating neuroblasts evade the
reelin-rich areas. But an experiment in which murine corticogenesis went
normally despite the malpositioned reelin secreting layer,
and lack of evidence that reelin affects the growth cones and leading
edges of neurons, caused some additional hypotheses to be proposed.
According to one of them, reelin makes the cells more susceptible to
some yet undescribed positional signaling cascade.
Reelin may also ensure correct neuronal positioning in the spinal cord: according to one study, location and level of its expression affects the movement of sympathetic preganglionic neurons.
The protein is thought to act on migrating neuronal precursors
and thus controls correct cell positioning in the cortex and other brain
structures. The proposed role is one of a dissociation signal for
neuronal groups, allowing them to separate and go from tangential
chain-migration to radial individual migration. Dissociation detaches migrating neurons from the glial cells that are acting as their guides, converting them into individual cells that can strike out alone to find their final position.
Top:
Representative image of somatic reelin immunoreactivities found in
12-day-in-vitro hippocampal neurons. Bottom: reelin immunofluorescence
(red) overlaid with
MAP2 counterstain (green). A fragment of an
illustration from Campo et al., 2009.
Reelin takes part in the developmental change of NMDA receptor configuration, increasing mobility of NR2B-containing receptors and thus decreasing the time they spend at the synapse.
It has been hypothesized that this may be a part of the mechanism
behind the "NR2B-NR2A switch" that is observed in the brain during its
postnatal development. Ongoing reelin secretion by GABAergic hippocampal neurons is necessary to keep NR2B-containing NMDA receptors at a low level.
In adults
In
the adult nervous system, reelin plays an eminent role at the two most
active neurogenesis sites, the subventricular zone and the dentate
gyrus. In some species, the neuroblasts from the subventricular zone
migrate in chains in the rostral migratory stream
(RMS) to reach the olfactory bulb, where reelin dissociates them into
individual cells that are able to migrate further individually. They
change their mode of migration from tangential to radial, and begin
using the radial glia fibers as their guides. There are studies showing
that along the RMS itself the two receptors, ApoER2 and VLDLR, and their intracellular adapter DAB1 function independently of Reelin, most likely by the influence of a newly proposed ligand, thrombospondin-1.
In the adult dentate gyrus, reelin provides guidance cues for new
neurons that are constantly arriving to the granule cell layer from
subgranular zone, keeping the layer compact.
Reelin also plays an important role in the adult brain by modulating cortical pyramidal neuron dendritic spine expression density, the branching of dendrites, and the expression of long-term potentiation as its secretion is continued diffusely by the GABAergic cortical interneurons those origin is traced to the medial ganglionic eminence.
In the adult organism the non-neural expression is much less widespread, but goes up sharply when some organs are injured. The exact function of reelin upregulation following an injury is still being researched.
Evolutionary significance
Cajal-Retzius cells,
as drawn by Cajal in 1891. The development of a distinct layer of these
reelin-secreting cells played a major role in brain evolution.
Neuronal
development: mammals (left) and avians (right) have different patterns
of reelin expression (pink). Nomura T. et al., 2008.
Reelin-DAB1 interactions could have played a key role in the
structural evolution of the cortex that evolved from a single layer in
the common predecessor of the amniotes into multiple-layered cortex of contemporary mammals.
Research shows that reelin expression goes up as the cortex becomes
more complex, reaching the maximum in the human brain in which the
reelin-secreting Cajal-Retzius cells have significantly more complex
axonal arbour.
Reelin is present in the telencephalon of all the vertebrates studied
so far, but the pattern of expression differs widely. For example, zebrafish have no Cajal-Retzius cells at all; instead, the protein is being secreted by other neurons. These cells do not form a dedicated layer in amphibians, and radial migration in their brains is very weak.
As the cortex becomes more complex and convoluted, migration
along the radial glia fibers becomes more important for the proper
lamination. The emergence of a distinct reelin-secreting layer is
thought to play an important role in this evolution. There are conflicting data concerning the importance of this layer,
and these are explained in the literature either by the existence of an
additional signaling positional mechanism that interacts with the
reelin cascade, or by the assumption that mice that are used in such experiments have redundant secretion of reelin compared with more localized synthesis in the human brain.
Cajal-Retzius cells, most of which disappear around the time of birth, coexpress reelin with the HAR1
gene that is thought to have undergone the most significant
evolutionary change in humans compared with chimpanzee, being the most
"evolutionary accelerated" of the genes from the human accelerated regions. There is also evidence of that variants in the DAB1 gene have been included in a recent selective sweep in Chinese populations.
Mechanism of action
Receptors
Reelin's control of cell-cell interactions is thought to be mediated by binding of reelin to the two members of low density lipoprotein receptor gene family: VLDLR and the ApoER2.
The two main reelin receptors seem to have slightly different roles:
VLDLR conducts the stop signal, while ApoER2 is essential for the
migration of late-born neocortical neurons.
It also has been shown that the N-terminal region of reelin, a site
distinct from the region of reelin shown to associate with VLDLR/ApoER2
binds to the alpha-3-beta-1 integrin receptor. The proposal that the protocadherin CNR1 behaves as a Reelin receptor has been disproven.
As members of lipoprotein receptor superfamily, both VLDLR and ApoER2 have in their structure an internalization domain called NPxY motif. After binding to the receptors reelin is internalized by endocytosis, and the N-terminal fragment of the protein is re-secreted.
This fragment may serve postnatally to prevent apical dendrites of
cortical layer II/III pyramidal neurons from overgrowth, acting via a
pathway independent of canonical reelin receptors.
Reelin receptors are present on both neurons and glial cells. Furthermore, radial glia express the same amount of ApoER2 but being ten times less rich in VLDLR. beta-1 integrin receptors on glial cells play more important role in neuronal layering than the same receptors on the migrating neuroblasts.
Reelin-dependent strengthening of long-term potentiation is caused by ApoER2 interaction with NMDA receptor.
This interaction happens when ApoER2 has a region coded by exon 19.
ApoER2 gene is alternatively spliced, with the exon 19-containing
variant more actively produced during periods of activity. According to one study, the hippocampal reelin expression rapidly goes up when there is need to store a memory, as demethylases open up the RELN gene. The activation of dendrite growth by reelin is apparently conducted through Src family kinases and is dependent upon the expression of Crk family proteins, consistent with the interaction of Crk and CrkL with tyrosine-phosphorylated Dab1. Moreover, a Cre-loxP recombination mouse model that lacks Crk and CrkL in most neurons was reported to have the reeler phenotype, indicating that Crk/CrkL lie between DAB1 and Akt in the reelin signaling chain.
Signaling cascades
Reelin activates the signaling cascade of Notch-1, inducing the expression of FABP7 and prompting progenitor cells to assume radial glial phenotype. In addition, corticogenesis in vivo is highly dependent upon reelin being processed by embryonic neurons, which are thought to secrete some as yet unidentified metalloproteinases that free the central signal-competent part of the protein. Some other unknown proteolytic mechanisms may also play a role.
It is supposed that full-sized reelin sticks to the extracellular
matrix fibers on the higher levels, and the central fragments, as they
are being freed up by the breaking up of reelin, are able to permeate
into the lower levels. It is possible that as neuroblasts
reach the higher levels they stop their migration either because of the
heightened combined expression of all forms of reelin, or due to the
peculiar mode of action of the full-sized reelin molecules and its
homodimers.
The intracellular adaptor DAB1 binds to the VLDLR and ApoER2 through an NPxY motif and is involved in transmission of Reelin signals through these lipoprotein receptors. It becomes phosphorylated by Src and Fyn kinases and apparently stimulates the actin
cytoskeleton to change its shape, affecting the proportion of integrin
receptors on the cell surface, which leads to the change in adhesion. Phosphorylation of DAB1 leads to its ubiquitination and subsequent degradation, and this explains the heightened levels of DAB1 in the absence of reelin. Such negative feedback is thought to be important for proper cortical lamination.
Activated by two antibodies, VLDLR and ApoER2 cause DAB1
phosphorylation but seemingly without the subsequent degradation and
without rescuing the reeler phenotype, and this may indicate that a part of the signal is conducted independently of DAB1.
Reelin stimulates the progenitor cells to differentiate into radial glia, inducing the expression of radial glial marker
BLBP by affecting the
NOTCH1 cascade. A fragment of an
illustration from Keilani et al., 2008.
A protein having an important role in lissencephaly and accordingly called LIS1 (PAFAH1B1), was shown to interact with the intracellular segment of VLDLR, thus reacting to the activation of reelin pathway.
Complexes
Reelin molecules have been shown to form a large protein complex, a disulfide-linked homodimer. If the homodimer fails to form, efficient tyrosine phosphorylation of DAB1 in vitro fails. Moreover, the two main receptors of reelin are able to form clusters
that most probably play a major role in the signaling, causing the
intracellular adaptor DAB1 to dimerize or oligomerize in its turn. Such
clustering has been shown in the study to activate the signaling chain
even in the absence of Reelin itself. In addition, reelin itself can cut the peptide bonds holding other proteins together, being a serine protease, and this may affect the cellular adhesion and migration processes. Reelin signaling leads to phosphorylation of actin-interacting protein cofilin 1
at ser3; this may stabilize the actin cytoskeleton and anchor the
leading processes of migrating neuroblasts, preventing their further
growth.
Interaction with Cdk5
Cyclin-dependent kinase 5 (Cdk5), a major regulator of neuronal migration and positioning, is known to phosphorylate DAB1 and other cytosolic targets of reelin signaling, such as Tau, which could be activated also via reelin-induced deactivation of GSK3B, and NUDEL, associated with Lis1, one of the DAB1 targets. LTP induction by reelin in hippocampal slices fails in p35 knockouts.
P35 is a key Cdk5 activator, and double p35/Dab1, p35/RELN, p35/ApoER2,
p35/VLDLR knockouts display increased neuronal migration deficits, indicating a synergistic action of reelin → ApoER2/VLDLR → DAB1 and p35/p39 → Cdk5 pathways in the normal corticogenesis.
Possible pathological role
Lissencephaly
Disruptions of the RELN gene are considered to be the cause of the rare form of lissencephaly with cerebellar hypoplasia classed as a microlissencephaly called Norman-Roberts syndrome. The mutations disrupt splicing of the RELN mRNA transcript, resulting in low or undetectable amounts of reelin protein. The phenotype in these patients was characterized by hypotonia, ataxia,
and developmental delay, with lack of unsupported sitting and profound
mental retardation with little or no language development. Seizures and congenital lymphedema are also present. A novel chromosomal translocation causing the syndrome was described in 2007.
Schizophrenia
Reduced expression of reelin and its mRNA levels in the brains of schizophrenia sufferers had been reported in 1998 and 2000, and independently confirmed in postmortem studies of the hippocampus, cerebellum, basal ganglia, and cerebral cortex. The reduction may reach up to 50% in some brain regions and is coupled with reduced expression of GAD-67 enzyme, which catalyses the transition of glutamate to GABA. Blood levels of reelin and its isoforms are also altered in schizophrenia, along with mood disorders, according to one study.
Reduced reelin mRNA prefrontal expression in schizophrenia was found to
be the most statistically relevant disturbance found in the multicenter
study conducted in 14 separate laboratories in 2001 by Stanley
Foundation Neuropathology Consortium.
Epigenetic hypermethylation of DNA in schizophrenia patients is proposed as a cause of the reduction, in agreement with the observations dating from the 1960s that administration of methionine to schizophrenic patients results in a profound exacerbation of schizophrenia symptoms in sixty to seventy percent of patients.
The proposed mechanism is a part of the "epigenetic hypothesis for
schizophrenia pathophysiology" formulated by a group of scientists in
2008 (D. Grayson; A. Guidotti; E. Costa). A postmortem study comparing a DNA methyltransferase (DNMT1)
and Reelin mRNA expression in cortical layers I and V of schizophrenic
patients and normal controls demonstrated that in the layer V both DNMT1
and Reelin levels were normal, while in the layer I DNMT1 was threefold
higher, probably leading to the twofold decrease in the Reelin
expression.
There is evidence that the change is selective, and DNMT1 is
overexpressed in reelin-secreting GABAergic neurons but not in their
glutamatergic neighbours. Methylation inhibitors and histone deacetylase inhibitors, such as valproic acid, increase reelin mRNA levels, while L-methionine treatment downregulates the phenotypic expression of reelin.
One study indicated the upregulation of histone deacetylase HDAC1 in the hippocampi of patients.
Histone deacetylases suppress gene promoters; hyperacetylation of
histones was shown in murine models to demethylate the promoters of both
reelin and GAD67. DNMT1 inhibitors in animals have been shown to increase the expression of both reelin and GAD67, and both DNMT inhibitors and HDAC inhibitors shown in one study to activate both genes with comparable dose- and time-dependence. As one study shows, S-adenosyl methionine (SAM) concentration in patients' prefrontal cortex is twice as high as in the cortices of non-affected people. SAM, being a methyl group donor necessary for DNMT activity, could further shift epigenetic control of gene expression.
Chromosome region 7q22 that harbours the RELN gene is associated with schizophrenia, and the gene itself was associated with the disease in a large study that found the polymorphism rs7341475 to increase the risk of the disease in women, but not in men. The women that have the single-nucleotide polymorphism (SNP) are about 1.4 times more likely to get ill, according to the study.
Allelic variations of RELN have also been correlated with working
memory, memory and executive functioning in nuclear families where one
of the members suffers from schizophrenia. The association with working memory was later replicated. In one small study, nonsynonymous polymorphism Val997Leu of the gene was associated with left and right ventricular enlargement in patients.
One study showed that patients have decreased levels of one of reelin receptors, VLDLR, in the peripheral lymphocytes. After six months of antipsychotic
therapy the expression went up; according to authors, peripheral VLRLR
levels may serve as a reliable peripheral biomarker of schizophrenia.
Considering the role of reelin in promoting dendritogenesis, suggestions were made that the localized dendritic spine deficit observed in schizophrenia could be in part connected with the downregulation of reelin.
Reelin pathway could also be linked to schizophrenia and other
psychotic disorders through its interaction with risk genes. One example
is the neuronal transcription factor NPAS3, disruption of which is linked to schizophrenia and learning disability. Knockout mice lacking NPAS3 or the similar protein NPAS1 have significantly lower levels of reelin; the precise mechanism behind this is unknown. Another example is the schizophrenia-linked gene MTHFR, with murine knockouts showing decreased levels of reelin in the cerebellum. Along the same line, it is worth noting that the gene coding for the subunit NR2B that is presumably affected by reelin in the process of NR2B->NR2A developmental change of NMDA receptor composition, stands as one of the strongest risk gene candidates. Another shared aspect between NR2B and RELN is that they both can be regulated by the TBR1 transcription factor.
The heterozygous reeler mouse, which is haploinsufficient for the RELN gene, shares several neurochemical and behavioral abnormalities with schizophrenia and bipolar disorder, but the exact relevance of these murine behavioral changes to the pathophysiology of schizophrenia remains debatable.
As previously described, reelin plays a crucial role in
modulating early neuroblast migration during brain development.
Evidences of altered neural cell positioning in post-mortem
schizophrenia patient brains and changes to gene regulatory networks that control cell migration
suggests a potential link between altered reelin expression in patient
brain tissue to disrupted cell migration during brain development. To
model the role of reelin in the context of schizophrenia at a cellular
level, olfactory neurosphere-derived cells were generated from the nasal biopsies of schizophrenia patients, and compared to cells from healthy controls. Schizophrenia patient-derived cells have reduced levels of reelin mRNA and protein when compared to healthy control cells, but expresses the key reelin receptors and DAB1 accessory protein. When grown in vitro, schizophrenia patient-derived cells were unable to respond to reelin coated onto tissue culture surfaces; In contrast, cells derived from healthy controls were able to alter their cell migration when exposed to reelin.
This work went on to show that the lack of cell migration response in
patient-derived cells were caused by the cell's inability to produce
enough focal adhesions of the appropriate size when in contact with extracellular reelin.
More research into schizophrenia cell-based models are needed to look
at the function of reelin, or lack of, in the pathophysiology of
schizophrenia.
Bipolar disorder
Decrease in RELN expression with concurrent upregulation of DNMT1 is typical of bipolar disorder
with psychosis, but is not characteristic of patients with major
depression without psychosis, which could speak of specific association
of the change with psychoses.
One study suggests that unlike in schizophrenia, such changes are found
only in the cortex and do not affect the deeper structures in psychotic
bipolar patients, as their basal ganglia were found to have the normal
levels of DNMT1 and subsequently both the reelin and GAD67 levels were
within the normal range.
In a genetic study conducted in 2009, preliminary evidence requiring further DNA replication suggested that variation of the RELN gene (SNP rs362719) may be associated with susceptibility to bipolar disorder in women.
Autism
Autism is a neurodevelopmental disorder
that is generally believed to be caused by mutations in several
locations, likely triggered by environmental factors. The role of reelin
in autism is not decided yet.
Reelin was originally in 2001 implicated in a study finding associations between autism and a polymorphic GGC/CGG repeat
preceding the 5' ATG initiator codon of the RELN gene in an Italian
population. Longer triplet repeats in the 5' region were associated with
an increase in autism susceptibility.
However, another study of 125 multiple-incidence families and 68
single-incidence families from the subsequent year found no significant
difference between the length of the polymorphic repeats in affected and
controls. Although, using a family based association test larger reelin alleles were found to be transmitted more frequently than expected to affected children.
An additional study examining 158 subjects with German lineage likewise
found no evidence of triplet repeat polymorphisms associated with
autism.
And a larger study from 2004 consisting of 395 families found no
association between autistic subjects and the CGG triplet repeat as well
as the allele size when compared to age of first word.
In 2010 a large study using data from 4 European cohorts would find some evidence for an association between autism and the rs362780 RELN polymorphism.
Studies of transgenic mice have been suggestive of an association, but not definitive.
Temporal lobe epilepsy: granule cell dispersion
Decreased reelin expression in the hippocampal tissue samples from patients with temporal lobe epilepsy was found to be directly correlated with the extent of granule cell dispersion (GCD), a major feature of the disease that is noted in 45%–73% of patients. The dispersion, according to a small study, is associated with the RELN promoter hypermethylation.
According to one study, prolonged seizures in a rat model of mesial
temporal lobe epilepsy have led to the loss of reelin-expressing
interneurons and subsequent ectopic chain migration and aberrant
integration of newborn dentate granule cells. Without reelin, the
chain-migrating neuroblasts failed to detach properly. Moreover, in a kainate-induced mouse epilepsy model, exogenous reelin had prevented GCD, according to one study.
Alzheimer's disease
The Reelin receptors ApoER2 and VLDLR belong to the LDL receptor gene family. All members of this family are receptors for Apolipoprotein E
(ApoE). Therefore, they are often synonymously referred to as 'ApoE
receptors'. ApoE occurs in 3 common isoforms (E2, E3, E4) in the human
population. ApoE4 is the primary genetic risk factor for late-onset Alzheimer's disease.
This strong genetic association has led to the proposal that ApoE
receptors play a central role in the pathogenesis of Alzheimer's
disease. According to one study, reelin expression and glycosylation patterns are altered in Alzheimer's disease.
In the cortex of the patients, reelin levels were 40% higher compared
with controls, but the cerebellar levels of the protein remain normal in
the same patients.
This finding is in agreement with an earlier study showing the presence
of Reelin associated with amyloid plaques in a transgenic AD mouse
model.
A large genetic study of 2008 showed that RELN gene variation is
associated with an increased risk of Alzheimer's disease in women. The number of reelin-producing Cajal-Retzius cells is significantly decreased in the first cortical layer of patients. Reelin has been shown to interact with amyloid precursor protein, and, according to one in-vitro study, is able to counteract the Aβ-induced dampening of NMDA-receptor activity. This is modulated by ApoE isoforms, which selectively alter the recycling of ApoER2 as well as AMPA and NMDA receptors.
Cancer
DNA methylation patterns are often changed in tumours, and the RELN gene could be affected: according to one study, in the pancreatic cancer the expression is suppressed, along with other reelin pathway components
In the same study, cutting the reelin pathway in cancer cells that
still expressed reelin resulted in increased motility and invasiveness.
On the contrary, in prostate cancer the RELN expression is excessive and correlates with Gleason score. Retinoblastoma presents another example of RELN overexpression. This gene has also been seen recurrently mutated in cases of acute lymphoblastic leukaemia.
Other conditions
One genome-wide association study indicates a possible role for RELN gene variation in otosclerosis, an abnormal growth of bone of the middle ear.
In a statistical search for the genes that are differentially expressed
in the brains of cerebral malaria-resistant versus cerebral
malaria-susceptible mice, Delahaye et al. detected a significant
upregulation of both RELN and DAB1 and speculated on possible protective effects of such over-expression. In 2020, a study reported a novel variant in RELN
gene (S2486G) which was associated with ankylosing spondylitis in a
large family. This suggested a potential insight into the
pathophysiological involvement of reelin via inflammation and
osteogenesis pathways in ankylosing spondylitis, and it could broaden
the horizon toward new therapeutic strategies.
A 2020 study from UT Southwestern Medical Center suggests circulating
Reelin levels might correlate with MS severity and stages, and that
lowering Reelin levels might be a novel way to treat MS.
Factors affecting reelin expression
Increased
cortical reelin expression in the pups of "High LG" (licking and
grooming) rats. A figure from Smit-Righter et al., 2009
The expression of reelin is controlled by a number of factors besides the sheer number of Cajal-Retzius cells. For example, TBR1 transcription factor regulates RELN along with other T-element-containing genes.
On a higher level, increased maternal care was found to correlate with
reelin expression in rat pups; such correlation was reported in
hippocampus and in the cortex. According to one report, prolonged exposure to corticosterone significantly decreased reelin expression in murine hippocampi, a finding possibly pertinent to the hypothetical role of corticosteroids in depression.
One small postmortem study has found increased methylation of RELN gene
in the neocortex of persons past their puberty compared with those that
had yet to enter the period of maturation.
Psychotropic medication
As
reelin is being implicated in a number of brain disorders and its
expression is usually measured posthumously, assessing the possible
medication effects is important.
According to the epigenetic hypothesis, drugs that shift the balance in favour of demethylation
have a potential to alleviate the proposed methylation-caused
downregulation of RELN and GAD67. In one study, clozapine and sulpiride
but not haloperidol and olanzapine were shown to increase the
demethylation of both genes in mice pretreated with l-methionine. Valproic acid, a histone deacetylase inhibitor,
when taken in combination with antipsychotics, is proposed to have some
benefits. But there are studies conflicting the main premise of the
epigenetic hypothesis, and a study by Fatemi et al. shows no increase in
RELN expression by valproic acid; that indicates the need for further
investigation.
Fatemi et al. conducted the study in which RELN mRNA and reelin
protein levels were measured in rat prefrontal cortex following a 21-day
of intraperitoneal injections of the following drugs:
In 2009, Fatemi et al. published the more detailed work on rats using
the same medication. Here, cortical expression of several participants (VLDLR, DAB1, GSK3B) of the signaling chain was measured besides reelin itself, and also the expression of GAD65 and GAD67.
