Duplication of chicken defensin7 gene generated by gene conversion and homologous recombination

Abundant β-Defensin Copy Number Variations in Pigs

BACKGROUND/OBJECTIVES

β-defensins are a family of classical endogenous antimicrobial peptides involved in innate immune response. β-defensins are encoded by a large number of loci and known to show extensive copy number variations (CNVs) that may be useful as DNA markers for host resilience against pathogenic infections.

METHODS

We developed a quantitative PCR-based method to estimate the genomic copy numbers of 13 pig β-defensin (pBD) genes and analyzed the range and extent of CNVs across several commercial pig breeds.

RESULTS

We assessed 38 animals from four pure breeds and a crossbreed and observed CNVs ranging from two to five genomic copies from pBD114, pBD115, pBD119, pBD124, pBD128, and pBD129, indicating extensive individual variations of gene copy numbers of these genes within each breed. The mean copy numbers of these pBDs were lower in Landrace and higher in Berkshire than in other breeds. We also observed a strong correlation between the genomic copy number and their expression levels with the correlation coefficient (r) > 0.9 for pBD114, pBD119, and pBD129 in the kidney, with these genes being highly expressed.

CONCLUSIONS

Although we only analyzed 13 pBDs among 29 reported genes, our results showed the presence of extensive CNVs in β-defensins from pigs. The genomic copy number of β-defensins may contribute to improving animal resilience against pathogenic infections and other associated phenotypes.

Characterization of avian β-defensin genes in Galliformes reveals widespread evolutionary diversification and distinct evolutionary relationships with infection risk

BACKGROUND

Avian β-defensins (AvBDs) represent a key family of antimicrobial host defense peptides in birds. Accumulating evidence suggests that the evolutionary trajectory of β-defensin genes is specific to the gene, timescale, and species involved, implying that species-specific ecological and life-history differences drive divergent selective pressures on these genes. However, their evolutionary dynamics, particularly the interactions with ecological factors and life-history traits, remain insufficiently explored.

RESULTS

Through a comprehensive survey of 25 species spanning all major clades of Galliformes, 354 AvBD genes were identified. Comparative sequence analysis, genomic organization, and phylogenetic studies collectively reveal significant evolutionary diversification characterized by gene duplication, pseudogenization, and gene loss across these species. Notably, chicken AvBD3 exhibits significant differences in its coding regions, while AvBD6 and AvBD7 appear to have copy number variations, with species-specific paralogs of AvBD6 being especially prominent. Moreover, positive selection was more frequently observed in recently diverged gene lineages compared to ancestral ones. Using 70 samples from eight galliform species, the study further identified the prevalence of species-specific amino acid alleles. Phylogenetic comparative analysis demonstrated that the evolution of nine AvBD genes (AvBD2, -4, -5, -8, -9, -10, -11, -12, and -14) is significantly associated with specific ecological factors and life-history characteristics. Additionally, the evolutionary rates of these genes showed distinct relationship with inferred infection risk, likely reflecting the multifunctionality of β-defensins and potential trade-offs between immune defense and other biological functions.

CONCLUSIONS

This cross-species identification and systematic evolutionary analysis of AvBDs in Galliformes deepen our understanding of the co-evolution of host defense peptides, offering valuable insights into their natural biology and evolution, and paving the way for future applications as alternatives to traditional antibiotics.

β-Defensin gene copy number variation in cattle

β-Defensins are peptides with antimicrobial roles, characterized by a conserved tertiary structure. Beyond antimicrobial functions, they exhibit diverse roles in both the immune response and fertility, including involvement in sperm maturation and function. Copy number variation (CNV) of β-defensin genes is extensive across mammals, including cattle, with possible implications for reproductive traits and disease resistance. In this study, we comprehensively catalogue 55 β-defensin genes in cattle. By constructing a phylogenetic tree to identify human orthologues and lineage-specific expansions, we identify 1 : 1 human orthologues for 35 bovine β-defensins. We also discover extensive β-defensin gene CNV across breeds, with DEFB103, in particular, showing extensive multi-allelic CNV. By comparing β-defensin expression levels in testis from calves and adult bulls, we find that 14 β-defensins, including DEFB103, increase in expression during sexual maturation. Analysis of β-defensin gene expression levels in the caput of adult bull epididymis, and β-defensin gene copy number, in 94 matched samples shows expression levels of four β-defensins are correlated with genomic copy numbers, including DEFB103. We therefore demonstrate extensive CNV in bovine β-defensin genes, in particular DEFB103, with potential functional consequences for fertility.

Evolutionary diversification of defensins and cathelicidins in birds and primates

Divergent evolution for more than 310 million years has resulted in an avian immune system that is complex and more compact than that of primates, sharing much of its structure and functions. Not surprisingly, well conserved ancient host defense molecules, such as defensins and cathelicidins, have diversified over time. In this review, we describe how evolution influenced the host defense peptides repertoire, its distribution, and the relationship between structure and biological functions. Marked features of primate and avian HDPs are linked to species-specific characteristics, biological requirements, and environmental challenge.

Expanding duplication of the testis PHD Finger Protein 7 (PHF7) gene in the chicken genome

Gene duplications increase genetic and phenotypic diversity and occur in complex genomic regions that are still difficult to sequence and assemble. PHD Finger Protein 7 (PHF7) acts during spermiogenesis for histone-to-histone protamine exchange and is a determinant of male fertility in Drosophila and the mouse. We aimed to explore and characterise in the chicken genome the expanding family of the numerous orthologues of the unique mouse Phf7 gene (highly expressed in the testis), observing the fact that this information is unclear and/or variable according to the versions of databases. We validated nine primer pairs by in silico PCR for their use in screening the chicken bacterial artificial chromosome (BAC) library to produce BAC-derived probes to detect and localise PHF7-like loci by fluorescence in situ hybridisation (FISH). We selected nine BAC that highlighted nine chromosomal regions for a total of 10 distinct PHF7-like loci on five Gallus gallus chromosomes: Chr1 (three loci), Chr2 (two loci), Chr12 (one locus), Chr19 (one locus) and ChrZ (three loci). We sequenced the corresponding BAC by using high-performance PacBio technology. After assembly, we performed annotation with the FGENESH program: there were a total of 116 peptides, including 39 PHF7-like proteins identified by BLASTP. These proteins share a common exon-intron core structure of 8-11 exons. Phylogeny revealed that the duplications occurred first between chromosomal regions and then inside each region. There are other duplicated genes in the identified BAC sequences, suggesting that these genomic regions exhibit a high rate of tandem duplication. We showed that the PHF7 gene, which is highly expressed in the rooster testis, is a highly duplicated gene family in the chicken genome, and this phenomenon probably concerns other bird species.

Analysis of the Diversity of the AvBD Gene Region in Japanese Quail

The avian β-defensin (AvBD) gene region is an important component of the innate immune system, encoding a variety of antimicrobial peptides. The AvBD region forms a multigene cluster in a specific chromosomal region. Comparison of the AvBD region among various birds suggests the presence of defects, duplications, and pseudogenization at many loci. The AvBD region in certain galliform birds, namely chicken, turkey, and bobwhite quail, includes AvBD3, -6, and -7, with the latter exhibiting copy number variants (CNVs) in chickens. DNA for genomic analysis was extracted from the peripheral blood of 99 randomly selected quail (Coturnix japonica) from 6 inbred lines. Nine CjAvBD1 and 8 CjAvBD12 alleles were detected. Ten haplotypes, including three that were strain specific, were found in alleles from the quail AvBD1 (CjAvBD1) and -12 (CjAvBD12) loci. Next-generation sequencing was used to determine the nucleotide sequences of the CjAvBD gene region (56-70 kb) for 7 homozygous diplotypes of these 10 haplotypes. These 7 haplotypes contained between 12 and 16 CjAvBD genes and were composed of 11 common loci: CjAvBD1, -2, -4, -5, -8, -9, -10, -11, -12, -13, and -14, but lacked CjAvBD3 and -7. Furthermore, up to 5 CjAvBD101 (AvBD6 ortholog) CNVs were observed among the 7 haplotypes. In addition, we detected amino acid substitutions causing net charge mutations that could affect antimicrobial activity in CjAvBD4, -13, -14, and -101. These results suggest that the CjAvBD region is unique among the Galliformes and that its diversity results in potential functional variation in innate immunity.

Accumulation of genetic variants associated with immunity in the selective breeding of broilers

Background

To satisfy an increasing demand for dietary protein, the poultry industry has employed genetic selection to increase the growth rate of broilers by over 400% in the past 50 years. Although modern broilers reach a marketable weight of ~ 2 kg in a short span of 35 days, a speed twice as fast as a broiler 50 years ago, the expedited growth has been associated with several negative detrimental consequences. Aside from heart and musculoskeletal problems, which are direct consequences of additional weight, the immune response is also thought to be altered in modern broilers.

Results

Given that identifying the underlying genetic basis responsible for a less sensitive innate immune response would be economically beneficial for poultry breeding, we decided to compare the genomes of two unselected meat control strains that are representative of broilers from 1957 and 1978, and a current commercial broiler line. Through analysis of genetic variants, we developed a custom prioritization strategy to identify genes and pathways that have accumulated genetic changes and are biologically relevant to immune response and growth performance. Our results highlight two genes, TLR3 and PLIN3, with genetic variants that are predicted to enhance growth performance at the expense of immune function.

Conclusions

Placing these new genomes in the context of other chicken lines, reveal genetic changes that have specifically arisen in selective breeding programs that were implemented in the last 50 years.

Mapping Genes Is Good for You

I abandoned my original career choice of high school teaching to pursue dentistry and soon abandoned that path for genetics. The latter decision was due to a challenge by a professor that led to me reading Nobel speeches by pioneer geneticists before I had formal exposure to the subject. Even then, I was 15 years into my career before my interest in rodent genomes gave way to mapping cattle genes. Events behind these twists and turns in my career path comprise the first part of this review. The remainder is a review of the development of the field of bovine genomics from my personal perspective. I have had the pleasure of working with outstanding graduate students, postdocs, and colleagues to contribute my small part to a discipline that has evolved from a few individuals mapping an orphan genome to a discipline underlying a revolution in animal breeding.

Genomic Structure and Tissue Expression of the NK-Lysin Gene Family in Bison

Antimicrobial peptides (AMPs) are a class of natural peptides with varying numbers of amino acids. They are principal components of innate immunity in vertebrates, encoding natural antibiotics and providing a protective response against a broad range of microbes including those responsible for tuberculosis, an important disease in bison. NK-lysins are AMPs that have been described in various organisms and are coded by a single gene in several mammalian species, including human. Recently, we described a family of 4 NK-lysin genes in cattle. Here, we examined NK-lysin genes in bison and identified 4 bison paralogs (NK1, NK2A, NK2B, and NK2C), although the current bison genome assembly annotates only 2 (NK1 and NK2). Sequence and phylogenetic analysis support the triplication of NK2 prior to the most recent common ancestor of bison and cattle. Comparative mapping of bison and cattle paralogs indicates that the NK-lysin family is located on bison chromosome 11 with well-conserved synteny of flanking genes relative to cattle. The 3 bison NK-lysin2 genes share high sequence similarity with each other. RNA-seq analysis demonstrates that NK2A, NK2B, and NK2C are expressed primarily in the lung, whereas NK1 is expressed at low levels in all tissues studied. This tissue expression pattern differs from that previously reported for cattle, suggesting some divergence in function since the evolutionary separation of the 2 species.

Rapid Gene Family Evolution of a Nematode Sperm Protein Despite Sequence Hyper-conservation

Reproductive proteins are often observed to be the most rapidly evolving elements within eukaryotic genomes. The major sperm protein (MSP) is unique to the phylum Nematoda and is required for proper sperm locomotion and fertilization. Here, we annotate the MSP gene family and analyze their molecular evolution in 10 representative species across Nematoda. We show that MSPs are hyper-conserved across the phylum, having maintained an amino acid sequence identity of 83.5–97.7% for over 500 million years. This extremely slow rate of evolution makes MSPs some of the most highly conserved genes yet identified. However, at the gene family level, we show hyper-variability in both gene copy number and genomic position within species, suggesting rapid, lineage-specific gene family evolution. Additionally, we find evidence that extensive gene conversion contributes to the maintenance of sequence identity within chromosome-level clusters of MSP genes. Thus, while not conforming to the standard expectation for the evolution of reproductive proteins, our analysis of the molecular evolution of the MSP gene family is nonetheless consistent with the widely repeatable observation that reproductive proteins evolve rapidly, in this case in terms of the genomic properties of gene structure, copy number, and genomic organization. This unusual evolutionary pattern is likely generated by strong pleiotropic constraints acting on these genes at the sequence level, balanced against expansion at the level of the whole gene family.

Haplotype structure and copy number polymorphism of the beta-defensin 7 genes in diverse chicken breeds

Beta-defensins is a family of avian peptides related to the innate immune system. Copy number variation was recently reported for the avian beta-defensin 7 gene (AvBD7) between the highly inbred Leghorn and Fayoumi lines. Here, we examined copy number variants in 35 different chicken breeds and found that 31 of them have at least the same representation of the duplicated AvBD7 allele. We also found haplotypes upstream of the AvBD6 regions that are strongly linked to the AvBD7 duplication. We observed a strong linkage disequilibrium spanning of the upstream region of the AvBD6 gene, with two SNPs being flanking markers to detect duplication of the AvBD7.