Kristelle M. Mendoza

An integrated and comparative genetic map of the turkey genome

An integrated genetic linkage map was developed for the turkey (Meleagris gallopavo) that combines the genetic markers from the three previous mapping efforts. The UMN integrated map includes 613 loci arranged into 41 linkage groups. An additional 105 markers are tentatively placed within linkage groups based on two-point LOD scores and 19 markers remain unlinked. A total of 210 previously unmapped markers has been added to the UMN turkey genetic map. Markers from each of the 20 linkage groups identified in the Roslin map and the 22 linkage groups of the Nte map are incorporated into the new integrated map. Overall map distance contained within the 41 linkage groups is 3,365 cM (sex-averaged) with the largest linkage group (94 loci) measuring 533.1 cM. Average marker interval for the map was 7.86 cM. Sequences of markers included in the new map were compared to the chicken genome sequence by ‘BLASTN’. Significant similarity scores were obtained for 95.6% of the turkey sequences encompassing an estimated 91% of the chicken genome. A physical map of the chicken genome based on positions of the turkey sequences was built and 36 of the 41 turkey linkage groups were aligned with the physical map, five linkage groups remain unassigned. Given the close similarities between the turkey and chicken genomes, the chicken genome sequence could serve as a scaffold for a genome sequencing effort in the turkey.

Comparative analysis of microsatellite loci in chicken and turkey.

Cross-species amplification of 520 chicken microsatellite markers was tested by polymerase chain reaction with genomic DNA of the turkey (Meleagris gallopavo). Each primer pair was tested at six different combinations of annealing temperature and MgCl2 concentration. A total of 280 (54%) of the primer pairs produced amplification products. The majority of these products were similar, if not identical in size to those expected based on the fragment sizes of the corresponding chicken loci. Structure of the dinucleotide repeat and flanking sequences was examined for 13 turkey fragments (amplified with chicken primers) and 5 chicken fragments (amplified with turkey primers). Sequence analysis found a wide array of mutations between species in addition to differences in repeat length. To estimate the usefulness of the amplified loci for genetic mapping in the turkey, allelic polymorphism was determined for 57 of the 280 amplified loci. A total of 20 of 57 markers (35%) were polymorphic with an average of 1.4 alleles per locus. The results of this study suggest that approximately 20% of the chicken microsatellite markers will be useful for mapping the turkey genome.

Structure, Genetic Mapping, and Function of the Cytochrome P450 3A37 Gene in the Turkey (Meleagris gallopavo)

Cytochromes P450 (P450 for protein; CYP for gene) are a superfamily of membrane-bound hemoproteins that oxidize a large number of endogenous and exogenous compounds. Through oxidation reactions, these enzymes are often responsible for the toxic and carcinogenic effects of natural food-borne toxicants, such as the mycotoxin aflatoxin B1 (AFB1). Previous studies in our laboratory have shown that the extreme sensitivity of turkeys to AFB1 is in part explained by efficient hepatic P450-mediated epoxidation to the toxic and reactive metabolite the exo-AFB1-8,9-epoxide (AFBO). Using 3′-5′-rapid amplification of cDNA ends (RACE), we amplified CYP3A37 from turkey liver RNA, the E. coli-expressed protein which efficiently epoxidates AFB1. Turkey CYP3A37 has an ORF of 1512 bp, and the protein is predicted to be 504 amino acids with 97% homology to chicken CYP3A37. The turkey gene is organized into 13 exons and 12 introns. A single nucleotide polymorphism in the 11th intron was used to assign CYP3A37 to turkey linkage group 10 (corresponding to chicken chromosome 14, GGA14). Because of the important role of P450s in the extreme sensitivity of turkeys to the toxic effects of AFB1, this study will contribute to the identifying allelic variants of this important gene in poultry.

Comparative genomics identifies new alpha class genes within the avian glutathione S-transferase gene cluster

Glutathione S-transferases (GSTs: EC2.5.1.18) are a superfamily of multifunctional dimeric enzymes that catalyze the conjugation of glutathione (GSH) to electrophilic chemicals. In most animals and in humans, GSTs are the principal enzymes responsible for detoxifying the mycotoxin aflatoxin B(1) (AFB(1)) and GST dysfunction is a known risk factor for susceptibility towards AFB(1). Turkeys are one of the most susceptible animals known to AFB(1), which is a common contaminant of poultry feeds. The extreme susceptibility of turkeys is associated with hepatic GSTs unable to detoxify the highly reactive and electrophilic metabolite exo-AFB(1)-8,9-epoxide (AFBO). In this study, comparative genomic approaches were used to amplify and identify the alpha-class tGST genes (tGSTA1.1, tGSTA1.2, tGSTA1.3, tGSTA2, tGSTA3 and tGSTA4) from turkey liver. The conserved GST domains and four alpha-class signature motifs in turkey GSTs (with the exception of tGSTA1.1 which lacked one motif) confirm the presence of hepatic alpha-class GSTs in the turkey. Four signature motifs and conserved residues found in alpha-class tGSTs are (1) xMExxxWLLAAAGVE, (2) YGKDxKERAxIDMYVxG, (3) PVxEKVLKxHGxxxL and (4) PxIKKFLXPGSxxKPxxx. A BAC clone containing the alpha-class GST gene cluster was isolated and sequenced. The turkey alpha-class GTS genes genetically map to chromosome MGA2 with synteny between turkey and human alpha-class GSTs and flanking genes. This study identifies the alpha-class tGST gene cluster and genetic markers (SNPs, single nucleotide polymorphisms) that can be used to further examine AFB(1) susceptibility and resistance in turkeys. Functional characterization of heterologously expressed proteins from these genes is currently underway.

Greater prairie chickens have a compact MHC-B with a single class IA locus

The major histocompatibility complex (MHC) plays a central role in innate and adaptive immunity, but relatively little is known about the evolution of the number and arrangement of MHC genes in birds. Insights into the evolution of the MHC in birds can be gained by comparing the genetic architecture of the MHC between closely related species. We used a fosmid DNA library to sequence a 60.9-kb region of the MHC of the greater prairie chicken (Tympanuchus cupido), one of five species of Galliformes with a physically mapped MHC. Greater prairie chickens have the smallest core MHC yet observed in any bird species, and major changes are observed in the number and arrangement of MHC loci. In particular, the greater prairie chicken differs from other Galliformes in the deletion of an important class I antigen binding gene. Analysis of the remaining class IA gene in a population of greater prairie chickens in Wisconsin, USA revealed little evidence for selection at the region responsible for antigen binding.

Response of the hepatic transcriptome to aflatoxin B1 in domestic turkey (Meleagris gallopavo).

Dietary exposure to aflatoxin B1 (AFB1) is detrimental to avian health and leads to major economic losses for the poultry industry. AFB1 is especially hepatotoxic in domestic turkeys (Meleagris gallopavo), since these birds are unable to detoxify AFB1 by glutathione-conjugation. The impacts of AFB1 on the turkey hepatic transcriptome and the potential protection from pretreatment with a Lactobacillus-based probiotic mixture were investigated through RNA-sequencing. Animals were divided into four treatment groups and RNA was subsequently recovered from liver samples. Four pooled RNA-seq libraries were sequenced to produce over 322 M reads totaling 13.8 Gb of sequence. Approximately 170,000 predicted transcripts were de novo assembled, of which 803 had significant differential expression in at least one pair-wise comparison between treatment groups. Functional analysis linked many of the transcripts significantly affected by AFB1 exposure to cancer, apoptosis, the cell cycle or lipid regulation. Most notable were transcripts from the genes encoding E3 ubiquitin-protein ligase Mdm2, osteopontin, S-adenosylmethionine synthase isoform type-2, and lipoprotein lipase. Expression was modulated by the probiotics, but treatment did not completely mitigate the effects of AFB1. Genes identified through transcriptome analysis provide candidates for further study of AFB1 toxicity and targets for efforts to improve the health of domestic turkeys exposed to AFB1.

Characterization of expressed sequence tags from turkey skeletal muscle.

This study was designed to identify important muscle gene homologues in the turkey. Three skeletal muscle cDNA libraries representing distinct muscle developmental stages were constructed. A total of 20,042 clones were sequenced resulting in 13,023 finished high-quality sequences (trimmed, quality scored and masked) for analysis. Sequence clustering produced 1113 contigs and 4144 singletons (5257 putative transcripts). Sequences were compared by blastn to the chicken whole-genome sequence and to the Ensembl and NCBI databases to identify homologous sequences. These surveys indicated that most of the important muscle genes are included in the sequence collection. Examination of contigs identified 1288 single nucleotide polymorphisms and in 320 of those the minor allele was observed to be present in more than one sequence. This resource provides sequence variants for numerous genes in the turkey, as demonstrated by the SNP haplotypes that were constructed for 10 genes. Sequences obtained in this study provide the basis for constructing a skeletal muscle-focused microarray, a tool that will facilitate the analysis of genes expressed during turkey muscle development, as well as the expression of genes underlying the genetic basis of muscle characteristics associated with meat quality.

Development of 90 new bovine microsatellite loci.

Polymorphic genetic markers are important tools in the construction of comprehensive genetic maps. This paper reports on the isolation and characterization of 90 new bovine microsatellite (ms) loci from enriched genomic libraries. The sequence of one clone (locus MNB-85) showed significant similarity to an intron of the human promyelocytic leukemia zinc finger protein (PLZF) gene. Screening of bovine and porcine somatic cell panels places the bovine PLZF homolog on BTA-15 and the porcine PLZF homolog on SSC-9. The 90 new microsatellite loci increase the number of microsatellites available for cattle by >5%.

Structure and genetic mapping of the Cytochrome P450 gene (CYP1A5) in the turkey (Meleagris gallopavo)

Cytochromes P450 (P450) are a superfamily of membrane-bound hemoproteins that oxidize a large number of endogenous and exogenous compounds. The recently cloned P450 gene (CYP1A5) encodes the primary protein responsible for epoxidation of aflatoxin B1 (AFB1) in the turkey, an animal extremely sensitive to this mycotoxin. Hypersensitivity of turkeys to AFB1 was first demonstrated by association with ‘Turkey X Disease’ which caused widespread deaths of turkeys and other poultry throughout Europe in the 1960s, later shown to be caused by AFB1-contaminated feed. In this study, comparative genomic approaches were used to selectively amplify and sequence the introns and 3′ flanking region of CYP1A5. The structure of the CYP1A5 gene in the turkey is shown to be equivalent to that of the human CYP1A genes with seven exons of 38, 858, 127, 90, 124, 87 and 307 bp, respectively, and six introns. A single nucleotide polymorphism (SNP) in the 3′ UTR was used to assign CYP1A5 to turkey linkage group M16 (equivalent to chicken chromosome 10). The results of this study provide the framework for identifying allelic variants of this biochemically important P450 gene in poultry.

Heterologous expression and functional characterization of avian mu-class glutathione S-transferases

Hepatic glutathione S-transferases (GSTs: EC2.5.1.1.8) catalyze the detoxification of reactive electrophilic compounds, many of which are toxic and carcinogenic intermediates, via conjugation with the endogenous tripeptide glutathione (GSH). Glutathione S-transferase (GST)-mediated detoxification is a critical determinant of species susceptibility to the toxic and carcinogenic mycotoxin aflatoxin B1 (AFB1), which in resistant animals efficiently detoxifies the toxic intermediate produced by hepatic cytochrome P450 bioactivation, the exo-AFB1-8,9-epoxide (AFBO). Domestic turkeys (Meleagris gallopavo) are one of the most sensitive animals known to AFB1, a condition associated with a deficiency of hepatic GST-mediated detoxification of AFBO. We have recently shown that unlike their domestic counterparts, wild turkeys (Meleagris gallopavo silvestris), which are relatively resistant, express hepatic GST-mediated detoxification activity toward AFBO. Because of the importance of GSTs in species susceptibility, and to explore possible GST classes involved in AFB1 detoxification, we amplified, cloned, expressed and functionally characterized the hepatic mu-class GSTs tGSTM3 (GenBank accession no. JF340152), tGSTM4 (JF340153) from domestic turkeys, and a GSTM4 variant (ewGSTM4, JF340154) from Eastern wild turkeys. Predicted molecular masses of tGSTM3 and two tGSTM4 variants were 25.6 and 25.8kDa, respectively. Multiple sequence comparisons revealed four GSTM motifs and the mu-loop in both proteins. tGSTM4 has 89% amino acid sequence identity to chicken GSTM2, while tGSTM3 has 73% sequence identity to human GSTM3 (hGSTM3). Specific activities of Escherichia coli-expressed tGSTM3 toward 1-chloro-2,4-dinitrobenzene (CDNB) and peroxidase activity toward cumene hydroperoxide were five-fold greater than tGSTM4 while tGSTM4 possessed more than three-fold greater activity toward 1,2-dichloro-4-nitrobenzene (DCNB). The two enzymes displayed equal activity toward ethacrynic acid (ECA). However, none of the GSTM proteins had AFBO detoxification capability, in contrast to recombinant alpha-class GSTs shown in our recent study to possess this important activity. In total, our data indicate that although turkey hepatic GSTMs may contribute to xenobiotic detoxification, they probably play no role in detoxification of AFBO in the liver.