Origin of the prolactin-releasing hormone (PRLH) receptors: evidence of coevolution between PRLH and a redundant neuropeptide Y receptor during vertebrate evolution

We present seven new vertebrate homologs of the prolactin-releasing hormone receptor (PRLHR) and show that these are found as two separate subtypes, PRLHR1 and PRLHR2. Analysis of a number of vertebrate sequences using phylogeny, pharmacology, and paralogon analysis indicates that the PRLHRs are likely to share a common ancestry with the neuropeptide Y (NPY) receptors. Moreover, a micromolar level of NPY was able to bind and inhibit completely the PRLH-evoked response in PRLHR1-expressing cells. We suggest that an ancestral PRLH peptide started coevolving with a redundant NPY binding receptor, which then became PRLHR, approximately 500 million years ago. The PRLHR1 subtype was shown to have a relatively high evolutionary rate compared to receptors with fixed peptide preference, which could indicate a drastic change in binding preference, thus supporting this hypothesis. This report suggests how gene duplication events can lead to novel peptide ligand/receptor interactions and hence spur the evolution of new physiological functions.     

Numerous groups of chromosomal regional paralogies strongly indicate two genome doublings at the root of the vertebrates

The appearance of the vertebrates demarcates some of the most far-reaching changes of structure and function seen during the evolution of the metazoans. These drastic changes of body plan and expansion of the central nervous system among other organs coincide with increased gene numbers. The presence of several groups of paralogous chromosomal regions in the human genome is a reflection of this increase. The simplest explanation for the existence of these paralogies would be two genome doublings with subsequent silencing of many genes. It is argued that gene localization data and the delineation of paralogous chromosomal regions give more reliable information about these types of events than dendrograms of gene families as gene relationships are often obscured by uneven replacement rates as well as other factors. Furthermore, the topographical relations of some paralogy groups are discussed.     

Early vertebrate chromosome duplications and the evolution of the neuropeptide Y receptor gene regions

Background  

One of the many gene families that expanded in early vertebrate evolution is the neuropeptide (NPY) receptor family of G-protein coupled receptors. Earlier work by our lab suggested that several of the NPY receptor genes found in extant vertebrates resulted from two genome duplications before the origin of jawed vertebrates (gnathostomes) and one additional genome duplication in the actinopterygian lineage, based on their location on chromosomes sharing several gene families. In this study we have investigated, in five vertebrate genomes, 45 gene families with members close to the NPY receptor genes in the compact genomes of the teleost fishes Tetraodon nigroviridis and Takifugu rubripes. These correspond to Homo sapiens chromosomes 4, 5, 8 and 10.     

Conserved synteny between the Ciona genome and human paralogons identifies large duplication events in the molecular evolution of the insulin-relaxin gene family

The aims of the study were to outline the sequence of eventsthat gave rise to the vertebrate insulin-relaxin gene familyand the chromosomal regions in which they reside. We analyzedthe gene content surrounding the human insulin/relaxin geneswith respect to what family they belonged to and if the duplicationhistory of investigated families parallels the evolution ofthe insulin-relaxin family members. Markov Clustering and phylogeneticanalysis were used to determine family identity. More than 15%of the genes belonged to families that have paralogs in theregions, defining two sets of quadruplicate paralogy regions.Thereby, the localization of insulin/relaxin genes in humansis in accordance with those regions on human chromosomes 1,11, 12, 19q (insulin/insulin-like growth factors) and 1, 6p/15q,9/5, 19p (insulin-like factors/relaxins) were formed duringtwo genome duplications. We compared the human genome with thatof Ciona intestinalis, a species that split from the vertebratelineage before the two suggested genome duplications. Two insulin-likeorthologs were discovered in addition to the already describedCi-insulin gene. Conserved synteny between the Ciona regionshosting the insulin-like genes and the two sets of human paralogonsimplies their common origin. Linkage of the two human paralogons,as seen in human chromosome 1, as well as the two regions hostingthe Ciona insulin-like genes suggests that a segmental duplicationgave rise to the region prior to the genome doublings. Thus,preserved gene content provides support that genome duplication(s)in addition to segmental and single-gene duplications shapedthe genomes of extant vertebrates.