Clustered protocadherin family

The brain is a complex system composed of enormous numbers of differentiated neurons, and brain structure and function differs among vertebrates. To examine the molecular mechanisms underlying brain structure and function, it is important to identify the molecules involved in generating neural diversity and organization. The clustered protocadherin (Pcdh) family is the largest subgroup of the diverse cadherin superfamily. The clustered Pcdh proteins are predominantly expressed in the brain and their gene structures in vertebrates are diversified. In mammals, the clustered Pcdh family consists of three gene clusters: Pcdh -α, Pcdh -β, and Pcdh -γ. During brain development, this family is upregulated by neuronal differentiation, and Pcdh-α is then dramatically downregulated by myelination. Clustered Pcdh expression continues in the olfactory bulb, hippocampus, and cerebellum until adulthood. Structural analysis of the first cadherin domain of the Pcdh-α protein revealed it lacks the features that classical cadherins require for homophilic adhesiveness, but it contains Pcdh-specific loop structures. In Pcdh-α, an RGD motif on a specific loop structure binds β1-integrin. For gene expression, the gene clusters are regulated by multiple promoters and alternative cis splicing. At the single-cell level, several dozen Pcdh -α and -γ mRNA are regulated monoallelically, resulting in the combinatorial expression of distinct variable exons. The Pcdh-α and Pcdh-γ proteins also form oligomers, further increasing the molecular diversity at the cell surface. Thus, the unique features of the clustered Pcdh family may provide the molecular basis for generating individual cellular diversity and the complex neural circuitry of the brain.     

原钙粘蛋白基因簇调控区域中成簇的CTCF结合位点分析

哺乳动物中原钙粘蛋白(Protocadherin, Pcdh)基因簇包含50多个串联排列的基因,这些基因形成3个紧密相连的基因簇(Pcdhα、Pcdhβ和Pcdhγ),所编码的原钙粘蛋白质群在神经元多样性(Neuronal diversity)和单细胞特异性(Single cell identity)以及神经突触信号转导中发挥重要作用。前期的工作已证实转录因子CTCF(CCCTC-binding factor)与CTCF结合位点(CTCF-binding site, CBS)的方向性结合能够决定增强子和启动子环化的方向以及其远距离交互作用的特异性,并进一步在Pcdh基因座(Locus)形成两个(Pcdhα和Pcdhγ)染色质拓扑结构域(CTCF/cohesin- mediated chromatin domain, CCD),而且染色质拓扑结构域对于控制基因表达调控至关重要。本文通过生物信息学方法对比人类和小鼠序列,发现Pcdhβγ染色质拓扑结构域调控区域中的DNase I超敏位点(DNase I hypersensitive sites, HSs)较为保守。染色质免疫沉淀及大规模测序实验(Chromatin immunoprecipitation and massive parallel sequencing, ChIP-Seq)揭示CBS位点在Pcdhβγ调控区域中成簇分布并且具有相同的方向。凝胶电泳迁移实验(Electrophoresis mobility shift assay, EMSA)确定Pcdhβγ调控区域内具体的42 bp CBS位点并且发现一个CTCF峰包含两个CBS位点。在全基因组范围内,运用计算生物学方法分析CTCF和增强子、启动子等调控元件的关系,发现CBS位点在调控元件附近有较多分布,推测CTCF通过介导增强子和启动子的特异性交互作用,在细胞核三维基因组内形成活性转录枢纽调控基因精准表达。     

Identification of the cluster control region for the protocadherin-beta genes located beyond the protocadherin-gamma cluster

The clustered protocadherins (Pcdhs), Pcdh-α, -β, and -γ, are transmembrane proteins constituting a subgroup of the cadherin superfamily. Each Pcdh cluster is arranged in tandem on the same chromosome. Each of the three Pcdh clusters shows stochastic and combinatorial expression in individual neurons, thus generating a hugely diverse set of possible cell surface molecules. Therefore, the clustered Pcdhs are candidates for determining neuronal molecular diversity. Here, we showed that the targeted deletion of DNase I hypersensitive (HS) site HS5-1, previously identified as a Pcdh-α regulatory element in vitro, affects especially the expression of specific Pcdh-α isoforms in vivo. We also identified a Pcdh-β cluster control region (CCR) containing six HS sites (HS16, 17, 17', 18, 19, and 20) downstream of the Pcdh-γ cluster. This CCR comprehensively activates the expression of the Pcdh-β gene cluster in cis, and its deletion dramatically decreases their expression levels. Deleting the CCR nonuniformly down-regulates some Pcdh-γ isoforms and does not affect Pcdh-α expression. Thus, the CCR effect extends beyond the 320-kb region containing the Pcdh-γ cluster to activate the upstream Pcdh-β genes. Thus, we concluded that the CCR is a highly specific regulatory unit for Pcdh-β expression on the clustered Pcdh genomic locus. These findings suggest that each Pcdh cluster is controlled by distinct regulatory elements that activate their expression and that the stochastic gene regulation of the clustered Pcdhs is controlled by the complex chromatin architecture of the clustered Pcdh locus.     

Molecular evolution of cadherin-related neuronal receptor/protocadherin(alpha) (CNR/Pcdh(alpha)) gene cluster in Mus musculus subspecies

The mouse cadherin-related neuronal receptor/protocadherin (CNR/Pcdh) gene clusters are located on chromosome 18. We sequenced single-nucleotide polymorphisms (SNPs) of the CNR/Pcdh(alpha)-coding region among 12 wild-derived and four laboratory strains; these included the four major subspecies groups of Mus musculus: domesticus, musculus, castaneus, and bactrianus. We detected 883 coding SNPs (cSNPs) in the CNR/Pcdh(alpha) variable exons and three in the constant exons. Among all the cSNPs, 586 synonymous (silent) and 297 nonsynonymous (amino acid exchanged) substitutions were found; therefore, the K(a)/K(s) ratio (nonsynonymous substitutions per synonymous substitution) was 0.51. The synonymous cSNPs were relatively concentrated in the first and fifth extracellular cadherin domain-encoding regions (ECs) of CNR/Pcdh(alpha). These regions have high nucleotide homology among the CNR/Pcdh(alpha) paralogs, suggesting that gene conversion events in synonymous and homologous regions of the CNR/Pcdh(alpha) cluster are related to the generation of cSNPs. A phylogenetic analysis revealed gene conversion events in the EC1 and EC5 regions. Assuming that the common sequences between rat and mouse are ancestral, the GC content of the third codon position has increased in the EC1 and EC5 regions, although biased substitutions from GC to AT were detected in all the codon positions. In addition, nonsynonymous substitutions were extremely high (11 of 13, K(a)/K(s) ratio 5.5) in the laboratory mouse strains. The artificial environment of laboratory mice may allow positive selection for nonsynonymous amino acid variations in CNR/Pcdh(alpha) during inbreeding. In this study, we analyzed the direction of cSNP generation, and concluded that subspecies-specific nucleotide substitutions and region-restricted gene conversion events may have contributed to the generation of genetic variations in the CNR/Pcdh genes within and between species.     

Inhibition of protocadherin-alpha function results in neuronal death in the developing zebrafish

The pcdhα/CNR gene comprises a diverse array of neuronal cell-surface proteins of the cadherin superfamily, although very little is known about their role in neural development. Here we provide the first in-depth characterization of pcdh1α in zebrafish. Whole-mount immunocytochemistry demonstrates that a large proportion of endogenous cytoplasmic domain immunoreactivity is present in the nucleus, suggesting that endoproteolytic cleavage and nuclear translocation of the intracellular domain are important aspects of pcdh1α activity in vivo. Using whole-mount immunocytochemistry and BAC-based expression of Pcdh1α-GFP fusion proteins, we find that Pcdh1α does not appear to form stable, synaptic puncta at early stages of synaptogenesis. We also demonstrate that the presence of the Pcdh1α cytoplasmic domain is essential for normal function. Truncation of Pcdh1α proteins, using splice-blocking antisense morpholinos to prevent the addition of the common intracellular domain to the entire pcdh1α cluster, results in neuronal apoptosis throughout the developing brain and spinal cord, demonstrating an essential role for pcdh1α in early neural development. This cell death phenotype can be attenuated by the expression of a soluble Pcdh1α cytoplasmic domain.     

Promoter choice determines splice site selection in protocadherin alpha and gamma pre-mRNA splicing

A family of mammalian protocadherin (Pcdh) proteins is encoded by three closely linked gene clusters (alpha, beta, and gamma). Multiple alpha and gamma Pcdh mRNAs are expressed in distinct patterns in the nervous system and are generated by alternative pre-mRNA splicing between different "variable" exons and three "constant" exons within each cluster. We show that each Pcdh variable exon is preceded by a promoter and that promoter choice determines which variable exon is included in a Pcdh mRNA. In addition, we provide evidence that alternative splicing of variable exons within a gene cluster occurs via a cis-splicing mechanism. However, virtually every variable exon can engage in trans-splicing with constant exons from another cluster, albeit at a far lower level.     

Functional significance of isoform diversification in the protocadherin gamma gene cluster

The mammalian Protocadherin (Pcdh) alpha, beta, and gamma gene clusters encode a large family of cadherin-like transmembrane proteins that are differentially expressed in individual neurons. The 22 isoforms of the Pcdhg gene cluster are diversified into A-, B-, and C-types, and the C-type isoforms differ from all other clustered Pcdhs in sequence and expression. Here, we show that mice lacking the three C-type isoforms are phenotypically indistinguishable from the Pcdhg null mutants, displaying virtually identical cellular and synaptic alterations resulting from neuronal apoptosis. By contrast, mice lacking three A-type isoforms exhibit no detectable phenotypes. Remarkably, however, genetically blocking apoptosis rescues the neonatal lethality of the C-type isoform knockouts, but not that of the Pcdhg null mutants. We conclude that the role of the Pcdhg gene cluster in neuronal survival is primarily, if not specifically, mediated by its C-type isoforms, whereas a separate role essential for postnatal development, likely in neuronal wiring, requires isoform diversity.     

Regulated ADAM10-dependent ectodomain shedding of gamma-protocadherin C3 modulates cell-cell adhesion

Gamma-protocadherins (Pcdh gamma) are type I transmembrane proteins, which are most notably expressed in the nervous system. They are enriched at synapses and involved in synapse formation, specification, and maintenance. In this study, we show that Pcdh gamma C3 and Pcdh gamma B4 are specifically cleaved within their ectodomains by the disintegrin and metalloprotease ADAM10. Analysis of ADAM10-deficient fibroblasts and embryos, inhibitor studies, as well as RNA interference-mediated down-regulation demonstrated that ADAM10 is not only responsible for the constitutive but also for the regulated shedding of these proteins in fibroblasts and in neuronal cells. In contrast to N-cadherin shedding, which was activated by N-methyl-D-aspartic acid receptor activation in neuronal cells, Pcdh gamma shedding was induced by alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid hydrate stimulation, suggesting differential regulation mechanisms of cadherin-mediated functions at synapses. Cell aggregation assays in the presence or absence of metalloprotease inhibitors strongly suggest that the ectodomain shedding events modulate the cell adhesion role of Pcdh gamma. The identification of ADAM10 as the protease responsible for constitutive and regulated Pcdh gamma shedding may therefore provide new insight into the regulation of Pcdh gamma functions.     

Protocadherin-19 and N-cadherin interact to control cell movements during anterior neurulation

The protocadherins comprise the largest subgroup within the cadherin superfamily, yet their cellular and developmental functions are not well understood. In this study, we demonstrate that pcdh 19 (protocadherin 19) acts synergistically with n-cadherin (ncad) during anterior neurulation in zebrafish. In addition, Pcdh 19 and Ncad interact directly, forming a protein-protein complex both in vitro and in vivo. Although both molecules are required for calcium-dependent adhesion in a zebrafish cell line, the extracellular domain of Pcdh 19 does not exhibit adhesive activity, suggesting that the involvement of Pcdh 19 in cell adhesion is indirect. Quantitative analysis of in vivo two-photon time-lapse image sequences reveals that loss of either pcdh 19 or ncad impairs cell movements during neurulation, disrupting both the directedness of cell movements and the coherence of movements among neighboring cells. Our results suggest that Pcdh 19 and Ncad function together to regulate cell adhesion and to mediate morphogenetic movements during brain development.     

A common protocadherin tail: Multiple protocadherins share the same sequence in their cytoplasmic domains and are expressed in different regions of brain

To study the diversity of protocadherins, a rat brain cDNA library was screened using a cDNA for the cytoplasmic domain of human protocadherin Pcdh2 as a probe. The resultant clones contained three different types. One type corresponds to rat Pcdh2; the other two types are distinct from Pcdh2 but contain the same sequence in their cytoplasmic domains and part of the 3′ flanking sequence. To clarify the structure of the proteins defined by the new clones, a putative entire coding sequence corresponding to one of the clones was determined. The overall structure is essentially the same as Pcdh2, indicating that the proteins defined by this clone, and probably by other clones, belong to the protocadherin family. Two PCR experiments and an RNase protection assay showed the existence of the corresponding mRNAs in rat brain preparations. Human and mouse cDNA clones with the same sequence properties were also isolated. Taken together, these results indicate that the clones are not cloning artifacts and that corresponding mRNAs are actually expressed in brains of various species. The results of in situ hybridization showed that the mRNAs corresponding to these clones were expressed in different regions in brain. Since protocadherins encoded by these mRNAs are likely to have different specificity in their interaction and share a common activity at their cytoplasmic domains, these protocadherins may provide a molecular basis, in part, to support the complex cell-cell interaction in brain.     

Expression of protocadherin-9 and protocadherin-17 in the nervous system of the embryonic zebrafish

In this study we analyzed expression patterns of two δ-protocadherins, protocadherin-9 and protocadherin-17, in the developing zebrafish using in situ hybridization and RT-PCR methods. Both protocadherins were mainly detected in the embryonic central nervous system, but each showed a distinct expression pattern. Protocadherin-9 message (Pcdh9) was expressed after 10 h post fertilization (hpf). It was found mainly in small clusters of cells in the anteroventral forebrain and ventrolateral hindbrain, and scattered cells throughout the spinal cord of young embryos (24 hpf). Pcdh9 expression in the hindbrain was segmental, reflecting a neuromeric organization, which became more evident at 34 hpf. As development proceeded, Pcdh9 expression increased throughout the brain, while its expression in the spinal cord was greatly reduced. Pcdh9 was also found in the developing retina and statoacoustic ganglion. Protocadherin-17 message (Pcdh17) expression began much earlier (1.5–2 hpf) than Pcdh9. Similar to Pcdh9 expression, Pcdh17 expression was found mainly in the anteroventral forebrain at 24 hpf, but its expression in the hindbrain and spinal cord, confined mainly to lateroventral regions of the hindbrain and anterior spinal cord, was more restricted than Pcdh9. As development proceeded, Pcdh17 expression was increased both in the brain and spinal cord: detected throughout the brain of two- and three-day old embryos, strongly expressed in the retina and in lateral regions of spinal cord in two-day old embryos. Its expression in the retina and spinal cord was reduced in three-day old embryos. Our results showed that expression of these two protocadherins was both spatially and temporally regulated.     

Extracellular matrix and matrix receptors in blood-brain barrier formation and stroke

The blood-brain barrier (BBB) is formed primarily to protect the brain microenvironment from the influx of plasma components, which may disturb neuronal functions. The BBB is a functional unit that consists mainly of specialized endothelial cells (ECs) lining the cerebral blood vessels, astrocytes, and pericytes. The BBB is a dynamic structure that is altered in neurologic diseases, such as stroke. ECs and astrocytes secrete extracellular matrix (ECM) proteins to generate and maintain the basement membranes (BMs). ECM receptors, such as integrins and dystroglycan, are also expressed at the brain microvasculature and mediate the connections between cellular and matrix components in physiology and disease. ECM proteins and receptors elicit diverse molecular signals that allow cell adaptation to environmental changes and regulate growth and cell motility. The composition of the ECM is altered upon BBB disruption and directly affects the progression of neurologic disease. The purpose of this review is to discuss the dynamic changes of ECM composition and integrin receptor expression that control BBB functions in physiology and pathology.     

The role and expression of the protocadherin-alpha clusters in the CNS

The clustered protocadherins comprise the largest subfamily of the cadherin superfamily and are predominantly expressed in the nervous system. The family of clustered protocadherins (clustered Pcdh family) is substructured into three distinct gene arrays in mammals: Pcdh-alpha, Pcdh-beta, and Pcdh-gamma. These are regulated by multiple promoters and cis-alternative splicing without DNA recombination. Pcdh-alpha proteins interact with beta1-integrin to promote cell adhesion. They also form oligomers with Pcdh-gamma proteins at the same membrane sites. During neuronal maturation, Pcdh-alpha expression is dramatically downregulated by myelination. The clustered Pcdh family has multiple variable exons that differ somewhat in number and sequence across vertebrate species. At the single-cell level, Pcdh-alpha mRNAs are regulated monoallelically, resulting in the combinatorial expression of distinct variable exons from each allele. These findings support the idea that diversified Pcdh molecules contribute to neural circuit development and provide individual cells with their specific identity.     

Parallel evolution of auditory genes for echolocation in bats and toothed whales

The ability of bats and toothed whales to echolocate is a remarkable case of convergent evolution. Previous genetic studies have documented parallel evolution of nucleotide sequences in Prestin and KCNQ4, both of which are associated with voltage motility during the cochlear amplification of signals. Echolocation involves complex mechanisms. The most important factors include cochlear amplification, nerve transmission, and signal re-coding. Herein, we screen three genes that play different roles in this auditory system. Cadherin 23 (Cdh23) and its ligand, protocadherin 15 (Pcdh15), are essential for bundling motility in the sensory hair. Otoferlin (Otof) responds to nerve signal transmission in the auditory inner hair cell. Signals of parallel evolution occur in all three genes in the three groups of echolocators--two groups of bats (Yangochiroptera and Rhinolophoidea) plus the dolphin. Significant signals of positive selection also occur in Cdh23 in the Rhinolophoidea and dolphin, and Pcdh15 in Yangochiroptera. In addition, adult echolocating bats have higher levels of Otof expression in the auditory cortex than do their embryos and non-echolocation bats. Cdh23 and Pcdh15 encode the upper and lower parts of tip-links, and both genes show signals of convergent evolution and positive selection in echolocators, implying that they may co-evolve to optimize cochlear amplification. Convergent evolution and expression patterns of Otof suggest the potential role of nerve and brain in echolocation. Our synthesis of gene sequence and gene expression analyses reveals that positive selection, parallel evolution, and perhaps co-evolution and gene expression affect multiple hearing genes that play different roles in audition, including voltage and bundle motility in cochlear amplification, nerve transmission, and brain function.     

Two novel CNRs from the CNR gene cluster have molecular features distinct from those of CNR1 to 8

Cadherin-related neuronal receptor (CNR) family proteins are known as synaptic cadherins and Reelin receptors. Here we have identified two novel mouse CNR genes, CNRc1 and CNRc2, orthologues of human protocadherin (Pcdh) alpha-c1 and Pcdhalpha-c2, respectively. While the variable large exons of CNRc1 and c2 contain six conserved extracellular cadherin repeats (EC1-6) and are linked to the constant exons, both contain several molecular features distinct from CNR1-8. CNRc1 and c2 lack the Arg-Gly-Asp (RGD) sequence that is conserved in the EC1 of CNR1-8, which is necessary for binding to Reelin. The present studies confirm that CNRc1 and c2 failed to immunoprecipitate with Reelin. In addition, the regulation of novel CNR expression patterns during brain development is slightly different from that of CNR1. The identification of these new CNR genes characterized by their distinct extracellular function and expression is indicative of the novel diversity of the processes of brain structuring and synapse regulation.