Porcine Parkin: Molecular cloning of PARK2 cDNA, expression analysis, and identification of a splicing variant

Enhanced mitophagy mediated by the YAP/Parkin pathway protects against DOX-induced cardiotoxicity

The clinical usage of Doxorubicin (DOX) is limited due to its cardiotoxicity. Although the precise mechanism remains unclear, there is an increasing body of evidence that has demonstrated that mitophagy is responsible for DOX-induced cardiotoxicity. In the present study, Parkin, a key protein for mitophagy initiation, was revealed to be downregulated in mouse hearts and in H9c2 cells upon DOX treatment. Enforced expression of Parkin led to mitophagy activation and attenuated cell apoptosis in H9c2 cells. Parkin transgenic mice inhibited DOX-induced cardiotoxicity. Furthermore, Yes-associatd protein, as a transcription co-activator, regulated the gene expression of Parkin, and in turn Parkin overexpression protected against cell apoptosis induced by DOX treatment. Taken together, enhanced mitophagy mediated by YAP/Parkin pathway protects against DOX-induced cardiotoxicity in mouse heart. These studies revealed the complex pathological process of DOX-induced cardiotoxicity and provided novel insight into potential chemotherapy targets.

Molecular cloning and characterization of porcine Na⁺/K⁺-ATPase isoform α4

Na⁺/K⁺-ATPase is responsible for maintaining electrochemical gradients of Na⁺ and K⁺, which is essential for a variety of cellular functions including neuronal activity. The α-subunit of the Na⁺/K⁺-ATPase is composed of four different polypeptides (α1-α4) encoded by different genes. Na,K-ATPase α4, encoded by the ATP1A4 gene, is expressed in testis and in male germ cells of humans, rats and mice. The α4 polypeptide has an important role in sperm motility, and is essential for male fertility. Here we present the RT-PCR cloning and characterization of the porcine ATP1A4 cDNA coding for Na⁺/K⁺-ATPase polypeptide α4. The Na⁺/K⁺-ATPase polypeptide α4, consisting of 1030 amino acids, displays a high homology with its human counterpart (86%). Phylogenetic analysis demonstrated that porcine Na⁺/K⁺-ATPase polypeptide α4 is closely related to other mammalian counterparts. In addition, the genomic structure of the porcine ATP1A4 gene was determined, and the intron-exon organization was found to be similar to that of the human ATP1A4 gene. The promoter sequence for the porcine ATP1A4 gene was also identified. Investigation of the genetic variation in the porcine ATP1A4 gene revealed a missense A/G SNP in exon 18. This A/G polymorphism results in a substitution of a methionine to a glycine residue (M888G). A very high overall DNA methylation rate of the ATP1A4 gene, 70-80%, was observed in both brain and liver. Expression analysis demonstrated that the porcine ATP1A4 gene is predominantly expressed in testis. The sequence of the porcine ATP1A4 cDNA encoding the Na⁺/K⁺-ATPase α4 protein has been submitted to GenBank under the accession number GenBank Accession No. MG587082.

Molecular characterization and analysis of the porcine NURR1 gene

Orphan receptor NURR1 (also termed NR4A2) belongs to the nuclear receptor superfamily and functions as a regulatory factor of differentiation, migration, maturation and maintenance of mesencephalic dopaminergic neurons. NURR1 plays an important role in nigrostriatal dopamine neuron development and is therefore implicated in the pathogenesis of neurodegenerative diseases linked to the dopamine system of the midbrain.

Here we report the isolation and characterization of porcine NURR1 cDNA. The NURR1 cDNA was RT-PCR cloned using NURR1-specific oligonucleotide primers derived from in silico sequences. The porcine NURR1 cDNA encodes a polypeptide of 598 amino acids, displaying a very high similarity with bovine, human and mouse (99%) NURR1 protein. Expression analysis revealed a differential NURR1 mRNA expression in various organs and tissues. NURR1 transcripts could be detected as early as at 60 days of embryo development in different brain tissues. A significant increase in NURR1 transcript in the cerebellum and a decrease in NURR1 transcript in the basal ganglia was observed during embryo development. The porcine NURR1 gene was mapped to chromosome 15. Two missense mutations were found in exon 3, the first coding exon of NURR1. Methylation analysis of the porcine NURR1 gene body revealed a high methylation degree in brain tissue, whereas methylation of the promoter was very low. A decrease in DNA methylation in a discrete region of the NURR1 promoter was observed in pig frontal cortex during pig embryo development. This observation correlated with an increase in NURR1 transcripts. Therefore, methylation might be a determinant of NURR1 expression at certain time points in embryo development.

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The porcine NURR1 gene was cloned and characterized.

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NURR1 transcript was detected early in pig embryo brain development.

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Methylation status of NURR1 may be a determinant for its expression.

Differential A-to-I RNA editing of the serotonin-2C receptor G-protein-coupled, HTR2C, in porcine brain tissues

The HTR2C gene encodes the 5-Hydroxytryptamine (serotonin) receptor 2C, G-protein-coupled protein which functions as a serotonin receptor. The HTR2C mRNA is subject to A-to-I RNA editing mediated by adenosine deaminases acting on RNA 1 and 2 (ADAR1 and ADAR2). In the current study we examined the molecular characteristics of the porcine HTR2C gene and determined the mRNA editing of the HTR2C transcript in different tissues. The A-to-I RNA editing of HTR2C was shown to be conserved in the porcine homologue with five nucleotides edited in exon 5. A differential editing was demonstrated with a high editing frequency in the frontal cortex, parietal cortex, occipital cortex, hypothalamus, brain stem and spinal cord and significantly lower in the cerebellum. No editing was seen in the liver and kidney. The porcine HTR2C gene was found to be exclusively expressed in brain tissues. The HTR2C gene was mapped to pig chromosome X. The methylation status of the HTR2C gene was examined in brain and liver by bisulfate sequencing and a high degree of methylation was found in the two tissues, at 89 and 72%, respectively. Our data describe differences in RNA editing in various regions of the porcine brain. The differences might reflect functional differences. Similarities between pigs and humans in differential RNA editing support the use of the pig as a model organism for the study of neurological diseases.

Porcine oocyte mtDNA copy number is high or low depending on the donor

Oocyte capacity is relevant in understanding decreasing female fertility and in the use of assisted reproductive technologies in human and farm animals. Mitochondria are important to the development of a functionally good oocyte and the oocyte mtDNA copy number has been introduced as a useful parameter for prediction of oocyte competence. The aim of this study was to investigate: (i) if the oocyte donor has an influence on its oocyte's mtDNA copy number; and (ii) the relation between oocyte size and mtDNA copy number using pre- and postpubertal pig oocytes. Cumulus-oocyte complexes were collected from individual donor pigs. The oocytes were allocated into different size-groups, snap-frozen and single-oocyte mtDNA copy number was estimated by quantitative real-time PCR using the genes ND1 and COX1. Results showed that mean mtDNA copy number in oocytes from any individual donor could be categorized as either 'high' (≥100,000) or 'low' (<100,000) with no difference in threshold between pre- and postpubertal oocytes. No linear correlation was detected between oocyte size and mtDNA copy number within pre- and postpubertal oocytes. This study demonstrates the importance of the oocyte donor in relation to oocyte mtDNA copy number, irrespectively of the donor's puberty status and the oocyte's growth stage. Observations from this study facilitate both further investigations of the importance of mtDNA copy number and the unravelling of relations between different mitochondrial parameters and oocyte competence.

Splicing variants of porcine synphilin-1

Parkinson's disease (PD), idiopathic and familial, is characterized by degradation of dopaminergic neurons and the presence of Lewy bodies (LB) in the substantia nigra. LBs contain aggregated proteins of which α-synuclein is the major component. The protein synphilin-1 interacts and colocalizes with α-synuclein in LBs. The aim of this study was to isolate and characterize porcine synphilin-1 and isoforms hereof with the future perspective to use the pig as a model for Parkinson's disease. The porcine SNCAIP cDNA was cloned by reverse transcriptase PCR. The spatial expression of SNCAIP mRNA was investigated by RNAseq. The presented work reports the molecular cloning and characterization of the porcine (Sus scrofa) synphilin-1 cDNA (SNCAIP) and three splice variants hereof. The porcine SNCAIP cDNA codes for a protein (synphilin-1) of 919 amino acids which shows a high similarity to human (90%) and to mouse (84%) synphilin-1. Three shorter transcript variants of the synphilin-1 gene were identified, all lacking one or more exons. SNCAIP transcripts were detected in most examined organs and tissues and the highest expression was found in brain tissues and lung. Conserved splicing variants and a novel splice form of synhilin-1 were found in this study. All synphilin-1 isoforms encoded by the identified transcript variants lack functional domains important for protein degradation.

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The full-length porcine SNCAIP cDNA encoding synphilin-1 was cloned and characterized.

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Three splicing variants of synphilin-1 were identified.

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Both conserved and novel splicing variant were found.

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SNCAIP mRNA was differently expressed in analyzed tissues and organs with highest expression in brain tissue and lung.

Porcine SLITRK1: Molecular cloning and characterization

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Molecular cloning of the porcine SLITRK1 gene is reported.

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A SLITRK1 transcript variant encoding a truncated protein was identified.

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The SLITRK1 transcript was exclusively expressed in brain tissues.

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There was low methylation of both the SLITRK1 gene body and its promoter.

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SLITRK1 was mapped to pig chromosome 11.

The membrane protein SLITRK1 functions as a developmentally regulated stimulator of neurite outgrowth and variants in this gene have been implicated in Tourette syndrome. In the current study we have cloned and characterized the porcine SLITRK1 gene. The genomic organization of SLITRK1 lacks introns, as does its human and mouse counterparts. RT-PCR cloning revealed two SLITRK1 transcripts: a full-length mRNA and a transcript variant that results in a truncated protein. The encoded SLITRK1 protein, consisting of 695 amino acids, displays a very high homology to human SLITRK1 (99%). The porcine SLITRK1 gene is expressed exclusively in brain tissues.

Cloning and characterization of the porcine DBC1 gene encoding deleted in bladder cancer

Deleted in bladder cancer 1 (DBC1) is a tumour suppressor which is involved in the regulation of cell growth and programmed cell death. In this study we report the cloning and characterization of porcine DBC1 cDNA. RT-PCR cloning produced a cDNA with an open reading frame of 2,283 bp encoding a polypeptide of 761 amino acids with a predicted molecular mass of 88.6 kDa and estimated isoelectric point of 9.1. The encoded pig DBC1 protein shows a very high amino acid similarity to human (99 %) and to mouse (98 %) DBC1. The porcine DBC1 gene was mapped to chromosome 1. The nucleotide sequence of the promoter displayed a high degree of conservation of elements responsible for neuron-specific expression. The porcine DBC1 gene was found to be highly expressed in brain tissues. The methylation status of the porcine DBC1 gene was examined in brain and liver by bisulfite sequencing. Methylation percentages of 53-61 were observed for the gene body whereas significantly lower values (1-4 %) were found in exon 1 and the promoter sequence of DBC1. The sequences of the porcine DBC1 cDNA and the DBC1 promoter and exon 1 sequence have been submitted to DDBJ/EMBL/GenBank under the accession numbers KF733442 and KJ396193, respectively.

Molecular cloning and characterization of porcine Na⁺/K⁺-ATPase isoforms α1, α2, α3 and the ATP1A3 promoter

Na⁺/K⁺-ATPase maintains electrochemical gradients of Na⁺ and K⁺ essential for a variety of cellular functions including neuronal activity. The α-subunit of the Na⁺/K⁺-ATPase exists in four different isoforms (α1-α4) encoded by different genes. With a view to future use of pig as an animal model in studies of human diseases caused by Na⁺/K⁺-ATPase mutations, we have determined the porcine coding sequences of the α1-α3 genes, ATP1A1, ATP1A2, and ATP1A3, their chromosomal localization, and expression patterns. Our ATP1A1 sequence accords with the sequences from several species at five positions where the amino acid residue of the previously published porcine ATP1A1 sequence differs. These corrections include replacement of glutamine 841 with arginine. Analysis of the functional consequences of substitution of the arginine revealed its importance for Na⁺ binding, which can be explained by interaction of the arginine with the C-terminus, stabilizing one of the Na⁺ sites. Quantitative real-time PCR expression analyses of porcine ATP1A1, ATP1A2, and ATP1A3 mRNA showed that all three transcripts are expressed in the embryonic brain as early as 60 days of gestation. Expression of α3 is confined to neuronal tissue. Generally, the expression patterns of ATP1A1, ATP1A2, and ATP1A3 transcripts were found similar to their human counterparts, except for lack of α3 expression in porcine heart. These expression patterns were confirmed at the protein level. We also report the sequence of the porcine ATP1A3 promoter, which was found to be closely homologous to its human counterpart. The function and specificity of the porcine ATP1A3 promoter was analyzed in transgenic zebrafish, demonstrating that it is active and drives expression in embryonic brain and spinal cord. The results of the present study provide a sound basis for employing the ATP1A3 promoter in attempts to generate transgenic porcine models of neurological diseases caused by ATP1A3 mutations.

Characterization of the porcine FBX07 gene: the first step towards generation of a pig model for Parkinsonian pyramidal syndrome

Parkinsonian pyramidal syndrome, also named pallido-pyramidal syndrome (PKPS), is the combination of early-onset progressive Parkinsonism with pyramidal tract signs. FBXO7, an F-box protein, is a component of modular E3 ubiquitin protein ligases called SCFs (SKP1, cullin, F-box proteins), which functions in phosphorylation-dependent ubiquitination. FBXO7 mutations cause autosomal recessive, early-onset PKPS. Here we report the molecular cloning and characterization of two isoforms of FBXO7 cDNA from pigs. The encoded FBXO7 protein displays a very high homology to human FBXO7 with an amino acid identity of 90%. Phylogenetic analysis demonstrated that porcine FBXO7 is closely related to other mammalian FBXO7 proteins. Furthermore, the genomic structure of the porcine FBXO7 gene was determined. The intron-exon structure is similar to that of the human FBXO7 gene. The promoter sequence for the porcine FBXO7 gene was also identified. A recognition site for miR-301a was found in the 3'UTR region of porcine FBXO7. Investigating the genetic variation in the porcine FBXO7 gene revealed a missense A/G SNP in exon 5. The A/G SNP results in a substitution of an asparagine to a serine residue (N269S). Using a radiation hybrid map the FBXO7 gene was mapped to pig chromosome 5. Real-time quantitative RT-PCR analysis revealed that FBXO7 mRNA is differentially expressed in many tissues and organs, and that FBXO7 transcript can be detected early in embryo development.

Porcine UCHL1: genomic organization, chromosome localization and expression analysis

The human UCHL1 gene encodes the ubiquitin C-terminal hydrolase UCHL1, which comprises more than 2% of total brain protein. UCHL1 is a component of the ubiquitin-proteasome system, which degrades overexpressed and damaged proteins. Mutations in the UCHL1 gene are associated with susceptibility to and protection from Parkinson's disease. Here we report cloning, characterization, expression analysis and mapping of porcine UCHL1. The UCHL1 cDNA was amplified by reverse transcriptase polymerase chain reaction (RT-PCR) using oligonucleotide primers derived from in silico sequences. The porcine cDNA codes for a protein of 223 amino acids which shows a very high similarity to human (98%) and to mouse (97%) UCHL1. In addition, the genomic organization of the porcine UCHL1 gene was determined. The porcine UCHL1 gene was mapped to chromosome 8(½p21)-p23. Three SNPs were found in the porcine UCHL1 sequence. Expression analysis by quantitative real time RT-PCR demonstrated that porcine UCHL1 mRNA is differentially expressed in various organs and tissues and similar to its human counterpart. UCHL1 transcript is most abundant in brain tissues and in the spinal cord. The UCHL1 mRNA expression was also investigated in developing porcine embryos. UCHL1 transcript was detected as early as 40 days of gestation. A significant decrease in UCHL1 transcript was detected in basal ganglia from day 60 to day 115 of gestation.

Threonine 53 in alpha-synuclein is conserved in long-living non-primate animals

Alpha-synuclein is the main constituent of Lewy bodies in familial and sporadic cases of Parkinson's disease (PD). Autosomal dominant point mutations, gene duplications or triplications in the alpha-synuclein (SNCA) gene cause hereditary forms of PD. One of the alpha-synuclein point mutations, Ala53Thr, is associated with increased oligomerization toxicity leading to familial early-onset PD in humans. The amino acid in position 53 in alpha-synuclein is an alanine in humans, great apes and Old World primates. However, this amino acid is a threonine in the alpha-synuclein of all other examined species, including New World monkeys. Here, we present DNA sequence analysis of SNCA and the deduced amino acid sequences of alpha-synuclein cloned from various different species, ranging from fish to mammals, which are known for their long-living potential. In all these investigated species the 53Thr is found. We conclude that 53Thr is not a molecular adaptation for long-living animals to minimize the risk of developing PD.

Molecular cloning, characterization and developmental expression of porcine beta-synuclein

The synuclein family includes three known proteins: alpha-synuclein, beta-synuclein and gamma-synuclein. beta-Synuclein inhibits the aggregation of alpha-synuclein, a protein involved in Parkinson's disease. We have cloned and characterized the cDNA sequence for porcine beta-synuclein (SNCB) from pig cerebellum using RT-PCR. Expression analysis by quantitative RT-PCR demonstrated that SNCB transcripts were highly abundant in brain tissues. SNCB mRNA was also detected early in embryogenesis and significant increases in transcript levels were observed in several brain tissues during embryo development. Radiation hybrid mapping data indicate that the porcine SNCB maps to the q arm of chromosome 2 (2q21-22). The subcellular localization of recombinant porcine beta-synuclein was determined in three different cell types and shown to be cytoplasmic.

A robust linkage map of the porcine autosomes based on gene-associated SNPs

BACKGROUND

Genetic linkage maps are necessary for mapping of mendelian traits and quantitative trait loci (QTLs). To identify the actual genes, which control these traits, a map based on gene-associated single nucleotide polymorphism (SNP) markers is highly valuable. In this study, the SNPs were genotyped in a large family material comprising more than 5,000 piglets derived from 12 Duroc boars crossed with 236 Danish Landrace/Danish Large White sows. The SNPs were identified in sequence alignments of 4,600 different amplicons obtained from the 12 boars and containing coding regions of genes derived from expressed sequence tags (ESTs) and genomic shotgun sequences.

RESULTS

Linkage maps of all 18 porcine autosomes were constructed based on 456 gene-associated and six porcine EST-based SNPs. The total length of the averaged-sex whole porcine autosome was estimated to 1,711.8 cM resulting in an average SNP spacing of 3.94 cM. The female and male maps were estimated to 2,336.1 and 1,441.5 cM, respectively. The gene order was validated through comparisons to the cytogenetic and/or physical location of 203 genes, linkage to evenly spaced microsatellite markers as well as previously reported conserved synteny. A total of 330 previously unmapped genes and ESTs were mapped to the porcine autosome while ten genes were mapped to unexpected locations.

CONCLUSION

The linkage map presented here shows high accuracy in gene order. The pedigree family network as well as the large amount of meiotic events provide good reliability and make this map suitable for QTL and association studies. In addition, the linkage to the RH-map of microsatellites makes it suitable for comparison to other QTL studies.

Sequence conservation between porcine and human LRRK2

Leucine-rich repeat kinase 2 (LRRK2) is a member of the ROCO protein superfamily (Ras of complex proteins (Roc) with a C-terminal Roc domain). Mutations in the LRRK2 gene lead to autosomal dominant Parkinsonism. We have cloned the porcine LRRK2 cDNA in an attempt to characterize conserved and therefore likely functional domains. The LRRK2 cDNA contains an open reading frame of 7,578 bp. The predicted LRRK2 protein consists of 2,526 amino acids of 86-93% identity with its mammalian couterparts. The deduced amino acid sequence of encoded porcine LRRK2 protein displays extensive homology with its human counterpart, with greatest similarities in those regions that contain the kinase domain, the Roc domain and the COR motif. Expression of porcine LRRK2 mRNA in various organs and tissues is similar to its human counterpart and not limited to the brain. The obtained data show that the LRRK2 sequence and expression patterns are conserved across species. The porcine LRRK2 gene was mapped to chromosome 5q25. The results obtained suggest that the LRRK2 gene might be of particular interest in our attempt to generate a transgenic porcine model for Parkinson's disease.

Porcine DJ-1: cloning of PARK7 cDNA, sequence comparison, expression analysis and chromosomal localization

The PARK7 gene encodes a protein, DJ-1, with several functions such as protection of cells from oxidative stress, sperm maturation and fertilization and chaperone activity. Mutations in the PARK7 gene are associated with autosomal recessive early-onset Parkinson's disease (Parkinsonism). This work reports the cloning and analysis of the porcine (Sus scrofa) homologue of DJ-1. The porcine PARK7 cDNA was amplified by reverse transcriptase polymerase chain reaction (RT-PCR) using oligonucleotide primers derived from in silico sequences. The porcine PARK7 cDNA (SsPARK7) encodes a protein of 189 amino acids which shows a very high similarity to bovine (97%), to human (96%) and to canine (95%) DJ-1. Protein structure comparison of human and porcine DJ-1 sequences revealed that amino acid changes were few between the two species and not likely to alter DJ-1 structure and function. Quantitative real-time RT-PCR detection exhibited SsPARK7 mRNA expression in all analyzed porcine tissues, although at different levels. Furthermore, expression analysis showed that SsPARK7 transcripts could be detected early in embryo development in different brain regions. The PARK7 gene was demonstrated to be located on porcine chromosome 6. Single-nucleotide polymorphism (SNP) analysis revealed one SNP in the porcine PARK7 gene, giving rise to a silent mutation in exon 6.