Comprehensive total evidence phylogeny of chinchillids (Rodentia, Caviomorpha): Cheek teeth anatomy and evolution.

Rodents are the most diverse order of extant mammals, and caviomorph rodents, or New World hystricognaths, have a remarkable morphological disparity and a long fossil record that begins in the Eocene. Chinchilloidea is a poorly understood clade within Caviomorpha, from an evolutionary and phylogenetic perspective. It includes the extant families Chinchillidae and Dinomyidae, the extinct Neoepiblemidae and Cephalomyidae, and several extinct chinchilloids without a clear phylogenetic position, like Eoincamys, Borikenomys, Chambiramys, Ucayalimys, Incamys, Saremmys, Garridomys and Scotamys. The family Chinchillidae includes the extant Chinchilla and Lagidium, grouped in Chinchillinae, and the only living Lagostominae, Lagostomus maximus. Among extinct chinchillids, Eoviscaccia (early Oligocene-early Miocene of Argentina, Bolivia and Chile), Prolagostomus (early-middle Miocene of Argentina, Bolivia and Chile) and Pliolagostomus (early-middle Miocene of Argentina) are the only genera originally described as members of the family. Based on the study of specimens with unworn or little-worn cheek teeth, belonging to extinct and extant taxa, we propose homologies of the cheek teeth structures and perform a combined molecular and morphological phylogenetic analysis including extinct and extant taxa of all families of Chinchilloidea and all genera of Chinchillidae. Our phylogenetic analysis recovered three major lineages in the evolutionary history of Chinchilloidea. The first major lineage is composed of the extant taxa Chinchilla, Lagidium and Lagostomus, and the extinct genera Eoviscaccia, Prolagostomus, Pliolagostomus, Garridomys, Incamys, Loncolicu and Saremmys. Cephalomyid (Banderomys, Cephalomys, Litodontomys, Soriamys) and neoepiblemid (Neoepiblema, Perimys, Phoberomys, Scotamys) genera are part of the second major lineage, while dinomyids such as Dinomys, Drytomomys, Scleromys, 'Scleromys' and Tetrastylus constitute the third major lineage within Chinchilloidea. The phylogenetic position of some taxa previously considered as incertae sedis chinchilloids or without a clear suprageneric group (i.e. Incamys, Saremmys, Garridomys and Loncolicu) show that they belong to pan-Chinchillidae and conform the stem Chinchillidae along with Eoviscaccia. The euhypsodont crown Chinchillidae includes the living subfamilies Chinchillinae and Lagostominae. Dinomyidae and Eoincamys pascuali are recovered as the sisters of a major clade composed by 'Cephalomyidae'+Neopiblemidae and pan-Chinchillidae, and Chambiramys sylvaticus occupies a basal position to the same clade. Four major radiation events are identified in the evolutionary history of Chinchilloidea. The analysis of new morphological characters linked with molecular evidence as well as the addition of taxa of uncertain or unstable phylogenetic position or not considered in previous studies allowed us resolve part of the relationships within Chinchilloidea, particularly that of Chinchillidae, supporting preceding morphological hypotheses.

The Year of the Rat: The Rat Genome Database at 20: a multi-species knowledgebase and analysis platform.

Formed in late 1999, the Rat Genome Database (RGD, https://rgd.mcw.edu) will be 20 in 2020, the Year of the Rat. Because the laboratory rat, Rattus norvegicus, has been used as a model for complex human diseases such as cardiovascular disease, diabetes, cancer, neurological disorders and arthritis, among others, for >150 years, RGD has always been disease-focused and committed to providing data and tools for researchers doing comparative genomics and translational studies. At its inception, before the sequencing of the rat genome, RGD started with only a few data types localized on genetic and radiation hybrid (RH) maps and offered only a few tools for querying and consolidating that data. Since that time, RGD has expanded to include a wealth of structured and standardized genetic, genomic, phenotypic, and disease-related data for eight species, and a suite of innovative tools for querying, analyzing and visualizing this data. This article provides an overview of recent substantial additions and improvements to RGD's data and tools that can assist researchers in finding and utilizing the data they need, whether their goal is to develop new precision models of disease or to more fully explore emerging details within a system or across multiple systems.

Biodistribution of [11C]-Metformin and mRNA Expression of Placentae Metformin Transporters in the Pregnant Chinchilla.

Background: While metformin is the first-line pharmacological treatment of diabetes mellitus type 2, this drug is not considered safe to use in pregnant women because of its unknown consequences for the fetus. In this study, we aimed to investigate the biodistribution of metformin in the pregnant chinchilla, a species exhibiting placental characteristics comparable with the pregnant woman. Furthermore, we aimed to investigate the expression of metformin transporters in humans and chinchillas, respectively, in order to evaluate the pregnant chinchilla as a novel animal model for the use of metformin in pregnancy. Methods: Three chinchillas in the last part of gestation were injected with [11C]-metformin and scanned by PET/CT for 70 minutes to visualize the distribution. To investigate the difference in expression of placenta transporters between humans and chinchillas, PCR was performed on samples from five chinchilla placentae and seven human placentae. Results: Dynamic PET with [11C]-metformin showed that the metformin distribution in chinchillas was similar to that in nonpregnant humans, with signal from kidneys, liver, bladder, and submandibular glands. Conversely, no radioactive signal was observed from the fetuses, and no metformin was accumulated in the chinchilla fetus when measuring the SUV. PCR of placental mRNA showed that the human placentae expressed OCT3, whereas the chinchilla placentae expressed OCT1. Conclusion: Since metformin did not pass the placenta barrier in the pregnant chinchilla, as it is known to do in humans, we do not suggest the chinchilla as a future animal model of metformin in pregnancies.

The Chinchilla Research Resource Database: resource for an otolaryngology disease model.

The long-tailed chinchilla (Chinchilla lanigera) is an established animal model for diseases of the inner and middle ear, among others. In particular, chinchilla is commonly used to study diseases involving viral and bacterial pathogens and polymicrobial infections of the upper respiratory tract and the ear, such as otitis media. The value of the chinchilla as a model for human diseases prompted the sequencing of its genome in 2012 and the more recent development of the Chinchilla Research Resource Database (http://crrd.mcw.edu) to provide investigators with easy access to relevant datasets and software tools to enhance their research. The Chinchilla Research Resource Database contains a complete catalog of genes for chinchilla and, for comparative purposes, human. Chinchilla genes can be viewed in the context of their genomic scaffold positions using the JBrowse genome browser. In contrast to the corresponding records at NCBI, individual gene reports at CRRD include functional annotations for Disease, Gene Ontology (GO) Biological Process, GO Molecular Function, GO Cellular Component and Pathway assigned to chinchilla genes based on annotations from the corresponding human orthologs. Data can be retrieved via keyword and gene-specific searches. Lists of genes with similar functional attributes can be assembled by leveraging the hierarchical structure of the Disease, GO and Pathway vocabularies through the Ontology Search and Browser tool. Such lists can then be further analyzed for commonalities using the Gene Annotator (GA) Tool. All data in the Chinchilla Research Resource Database is freely accessible and downloadable via the CRRD FTP site or using the download functions available in the search and analysis tools. The Chinchilla Research Resource Database is a rich resource for researchers using, or considering the use of, chinchilla as a model for human disease.Database URL: http://crrd.mcw.edu.

Parvovirus-derived endogenous viral elements in two South American rodent genomes.

We describe endogenous viral elements (EVEs) derived from parvoviruses (family Parvoviridae) in the genomes of the long-tailed chinchilla (Chinchilla lanigera) and the degu (Octodon degus). The novel EVEs include dependovirus-related elements and representatives of a clearly distinct parvovirus lineage that also has endogenous representatives in marsupial genomes. In the degu, one dependovirus-derived EVE was found to carry an intact reading frame and was differentially expressed in vivo, with increased expression in the liver.

A member of the cathelicidin family of antimicrobial peptides is produced in the upper airway of the chinchilla and its mRNA expression is altered by common viral and bacterial co-pathogens of otitis media.

Cationic antimicrobial peptides (AMPs), a component of the innate immune system, play a major role in defense of mucosal surfaces against a wide spectrum of microorganisms such as viral and bacterial co-pathogens of the polymicrobial disease otitis media (OM). To further understand the role of AMPs in OM, we cloned a cDNA encoding a cathelicidin homolog (cCRAMP) from upper respiratory tract (URT) mucosae of the chinchilla, the predominant host used to model experimental OM. Recombinant cCRAMP exhibited alpha-helical secondary structure and killed the three main bacterial pathogens of OM. In situ hybridization showed cCRAMP mRNA production in epithelium of the chinchilla Eustachian tube and RT-PCR was used to amplify cCRAMP mRNA from several other tissues of the chinchilla URT. Quantitative RT-PCR analysis of chinchilla middle ear epithelial cells (CMEEs) incubated with either viral (influenza A virus, adenovirus, or RSV) or bacterial (nontypeable H. influenzae, M. catarrhalis, or S. pneumoniae) pathogens associated with OM demonstrated distinct microbe-specific patterns of altered expression. Collectively, these data showed that viruses and bacteria modulate AMP messages in the URT, which likely contributes to the disease course of OM.

Mucin gene cDNA sequence characterization in chinchilla middle ear epithelium.

OBJECTIVES: To identify mucin genes in chinchilla middle ear epithelium and characterize complimentary deoxyribonucleic acid (cDNA) sequences to facilitate further investigations into mucin physiology and pathophysiology on a molecular level using the chinchilla model. METHODS: Chinchilla mucin gene exploration and cDNA characterization was accomplished using reverse transcriptase-polymerase chain reactions (RT-PCR). Forward and reverse primer pairs were designed using consensus sequences available for human and rodent species. Chinchilla middle ear epithelium was harvested and primary cell cultures (CMEEC) were established. The CMEEC were explored for the expression of chinchilla mucin genes 1, 2, 4 and 5AC (cMuc1, cMuc2, cMuc4 and cMuc5AC). Identified cDNA amplicons for each of these genes was sequenced and homology compared to previously published human and rodent sequences. RESULTS: CMEEC express all four of the mucin genes cMuc1, cMuc2, cMuc4 and cMuc5AC. cDNA amplicons for each of the genes were able to be sequenced with lengths ranging from 66 to 362 base pairs. Each of the chinchilla cDNA sequences expressed significant homology with published human and rodent cDNA for these mucin genes. A cDNA sequence for the housekeeping gene, beta-actin, was also identified. CONCLUSIONS: Chinchilla middle ear epithelium grown in culture expresses the mucin genes 1, 2, 4 and 5AC, which have been identified as important in mucin regulation in the middle ear. cDNA sequences corresponding to these mucin genes were identified and may serve as important molecular tools in future studies of otitis media using the chinchilla model.

Single nucleotide polymorphisms in exon 10 of the chinchilla growth hormone receptor (GHR) gene.

The aim of this study was to detect SNPs in exon 10 of the chinchilla growth hormone receptor gene (GHR) by comparative sequencing. Sixty females of the same breed (Standard) were analysed. Four new SNPs were identified, which cause 3 amino acid substitutions in the intracellular domain of the receptor: G/C at position 135 bp (in relation to the total sequence of exon 10) (gln/his), CAG/AAA at 352 bp and 354 bp (gln/lys), and C/A at 641 bp (thr/asn).

Molecular systematics of hystricognath rodents: evidence from the mitochondrial 12S rRNA gene.

Nucleotide sequence variation among 22 representatives of 14 families of hystricognathid rodents was examined using an 814-bp region of the mitochondrial 12S ribosomal RNA (rRNA) gene composing domains I-III. The purpose of this study was twofold. First, the phylogenetic relationships among Old World phiomorph (primarily African) and New World caviomorph (primarily South American) families were investigated, with a special emphasis on testing hypotheses pertaining to the origin of New World families and the identification of major monophyletic groups. Second, divergence times derived from molecular data were compared to those suggested by the fossil record. The resultant 12S rRNA gene phylogeny, analyzed separately and in combination with other morphological and molecular data, supported a monophyletic Caviomorpha. This finding is counter to the idea of a multiple origin for the South American families. The most strongly supported relationships within the Caviomorpha were a monophyletic Octodontoidea (containing five families) and the placement of New World porcupines (family Erethizontidae) as the most divergent family. Although comparisons to other data were more equivocal, the most parsimonious 12S rRNA trees also supported a monophyletic Phiomorpha that could be subdivided into two major groups, a clade containing the Thryonomyoidea (Thryonomyidae and Petromuridae) plus Bathyergidae and the more divergent Hystricidae (Old World porcupines). No significant differences in rates of 12S rRNA gene divergence were observed for hystricognathids in comparison to other rodent groups. Although time since divergence estimates were influenced by the fossil dates chosen to calibrate absolute rates, the overall divergence times derived from both transversions only and Kimura corrected distances and calibrations using two independent dates revealed a divergence time between Old and New World groups dating in the Eocene.

Inhibition of vasopressin and aldosterone release by atrial natriuretic peptide in conscious rabbits.

To elucidate the regulatory role of atrial natriuretic factor (ANF) on vasopressin (AVP) and aldosterone release in conscious rabbits, ANF was administered systematically at a rate of 15 pmol min-1 (kg body wt)-1 for 15 min in two series of experimental animals in which AVP and/or aldosterone production was stimulated. In euhydrated rabbits (series I), systemic administration of angiotensin II (Ang II) (10 pmol min-1 (kg body wt)-1, 15 min) stimulated aldosterone release threefold from basal plasma concentrations (140 pg ml-1). The co-application of ANF inhibited the Ang II-induced release of aldosterone without influencing the non-stimulated AVP system. In dehydrated rabbits (series II) with elevated plasma osmolality and AVP concentration, exogenously applied ANF increased plasma ANF fourfold at marginally reduced arterial pressure. Plasma AVP concentrations were reduced by 3.4 pg ml-1 (25%) on average, and plasma aldosterone concentrations were lowered by 34 pg ml-1 (23%) at unchanged levels of plasma corticosterone. Receptor binding studies using [125I]ANF as radioligand revealed Ang II-independent high-affinity receptors for ANF in the zona glomerulosa of the adrenal gland. With regard to the hypothalamo-neurohypophyseal AVP system, ANF binding sites were localized to the median eminence and neurohypophysis, but not to the magnocellular nuclei. ANF receptors were also labelled in structures lacking a blood-brain barrier such as the subfornical organ and the choroid plexus.