Selecting chicken for improved meat production has altered the relative growth of organs in modern broiler lines compared with heritage lines. In this study, we compared the growth and feed efficiency of a heritage line, UIUC, with a modern production line, Ross 708, for 5 wk posthatch. During this period, the BW and feed efficiency of the modern strain was higher than that of the heritage line, indicating that the Ross 708 birds were more efficient than the UIUC birds at converting feed to body mass. The relative growth of the breast, heart, liver, and intestine were also compared during these 5 wk. The breast muscle of the heritage line constituted 9% of the total body mass at 5 wk, whereas in the modern line, the breast muscle was 18% of the total mass of the bird. In contrast, the relative size of the heart decreased after d 14 in the modern line, suggesting that selection for increased breast muscle has translated into relatively less weight of the heart muscle. The liver matured earlier in modern lines, possibly improving nutrient utilization as the birds shift from lipid- to carbohydrate-rich feed. Finally, jejunal and ileal sections of the intestine were 20% longer in the modern line, perhaps allowing for increased nutrient absorption.
Accurate and complete genome sequences are essential in biotechnology to facilitate genome-based cell engineering efforts. The current genome assemblies for Cricetulus griseus, the Chinese hamster, are fragmented and replete with gap sequences and misassemblies, consistent with most short-read based assemblies. Here, we completely resequenced C. griseus using Single Molecule Real Time (SMRT) sequencing and merged this with Illumina-based assemblies. This generated a more contiguous and complete genome assembly than either technology alone, reducing the number of scaffolds by >28-fold, with 90% of the sequence in the 122 longest scaffolds. Most genes are now found in single scaffolds, including up- and downstream regulatory elements, enabling improved study of noncoding regions. With >95% of the gap sequence filled, important CHO cell mutations have been detected in draft assembly gaps. This new assembly will be an invaluable resource for continued basic and pharmaceutical research.
Identification of Avian Infectious Bronchitis Virus by Direct Automated Cycle Sequencing of the S-1 Gene
Direct automated cycle sequencing (DACS) of a reverse transcription-polymerase chain reaction (RT-PCR) product of the S-1 subunit of the spike peplomer gene was used to identify infectious bronchitis virus (IBV) serotypes. Degenerate primers CK4 and CK2, utilized previously in our laboratory, were selected for DACS because they successfully amplify a wide range of serotypes represented by various reference strains and field isolates and the resulting polymerase chain reaction (PCR) product contains diagnostically relevant S-1 sequences that can be used to identify the serotype of IBV. The S-1 nucleotide sequences generated by DACS were aligned and analyzed with commercial software to determine their relationship to the S-1 nucleotide sequences of IBV strains on deposit in the GenBank and EMBL databases. Reference strains Massachusetts (Mass) 41, Connecticut (Conn), Arkansas (Ark) DPI, JMK, and DE/072/92 were initially tested by DACS to establish the feasibility of the procedure. The DACS procedure was further evaluated with a panel of "unknowns" comprised of IBV reference strains, field isolates, and variant serotypes collected by our laboratory. The DACS procedure provided high-quality and reproducible S-1 sequence for all IBV serotypes tested, including variant serotypes that had not been sequenced previously. The S-1 nucleotide sequences for the amplified PCR products of reference strains Mass 41, Conn, Ark DPI, JMK, and DE/072/92 generated by DACS were highly homologous (>99% nucleotide identity) with their respective GenBank database sequences. In the unknown panel, the nucleotide identities of the DACS S-1 sequences of field isolates of serotypes previously identified by virus neutralization were also found to be very high (> or = 95.5%) after alignment with database sequences. In contrast, the nucleotide identities of S-1 sequences of variant serotypes 37, 3330, and PA/1220/98 and reference strain Clark 333, for which database sequences were not available, ranged from 27.7% to 73.8%, well below the identity values for a homologous serotype. With alignment software, the identities of strains in mixtures of RNAs of two different serotypes were not resolvable. DACS of IBV S-1 RT-PCR products will enable researchers to rapidly identify field strains, including new, previously unrecognized variant virus serotypes.
In grasses, two pathways that generate diverse and numerous 21-nt (premeiotic) and 24-nt (meiotic) phased siRNAs are highly enriched in anthers, the male reproductive organs. These "phasiRNAs" are analogous to mammalian piRNAs, yet their functions and evolutionary origins remain largely unknown. The 24-nt meiotic phasiRNAs have only been described in grasses, wherein their biogenesis is dependent on a specialized Dicer (DCL5). To assess how evolution gave rise to this pathway, we examined reproductive phasiRNA pathways in nongrass monocots: garden asparagus, daylily, and lily. The common ancestors of these species diverged approximately 115-117 million years ago (MYA). We found that premeiotic 21-nt and meiotic 24-nt phasiRNAs were abundant in all three species and displayed spatial localization and temporal dynamics similar to grasses. The miR2275-triggered pathway was also present, yielding 24-nt reproductive phasiRNAs, and thus originated more than 117 MYA. In asparagus, unlike in grasses, these siRNAs are largely derived from inverted repeats (IRs); analyses in lily identified thousands of precursor loci, and many were also predicted to form foldback substrates for Dicer processing. Additionally, reproductive phasiRNAs were present in female reproductive organs and thus may function in both male and female germinal development. These data describe several distinct mechanisms of production for 24-nt meiotic phasiRNAs and provide new insights into the evolution of reproductive phasiRNA pathways in monocots.
Emergence of Subtype Strains of the Arkansas Serotype of Infectious Bronchitis Virus in Delmarva Broiler Chickens
Infectious bronchitis virus (IBV) field isolates of the Arkansas (Ark) serotype were identified by reverse transcription-polymerase chain reaction (RT-PCR) as the most common serotype isolated from 1993 to 1997. These isolates were recovered from broiler flocks with respiratory disease raised on the Delmarva peninsula in spite of Ark vaccination in the region. For the purposes of investigating this apparently paradoxical finding, five RT-PCR Ark-positive field isolates recovered in 1995 and 1996 were selected for further characterization. The isolates were compared with Ark reference strains by reciprocal virus neutralization (VN) in embryonated eggs, S-1 gene sequence analysis, and challenge of immunity studies in specific-pathogen-free (SPF) chickens. Antigenic (VN) comparisons and S-1 gene analysis confirmed that the five RT-PCR Ark-positive field isolates were of the Ark serotype but also revealed that the viruses could be readily distinguished from Ark reference strains. Four of the isolates (Ark/213/96, Ark/15C/96, Ark/1529/95, Ark/1534/95) were found to have higher antigenic relatedness percentages to each other (95%-100%) than to Ark reference strains DPI (52%-72%) and Georgia variant (Georgia var) (53%-68%) by VN. Another isolate, Ark/1535/95, was found to differ antigenically from the other four RT-PCR Ark-positive field isolates (34%-61%), Ark DPI (44%), and Georgia var (43%) strains. The trends in the S-1 gene sequencing results were similar to those observed for the VN findings. Isolates Ark/213/96, Ark/15C/96, Ark/1529/95, and Ark/1534/95 demonstrated a higher degree of predicted S-1 amino acid similarity to each other (96.5%-98.7%) than to Ark DPI (92.4%-93.7%), Ark 99 (93.2%-94.7%), and Georgia var (89.3%-90.8%). Ark/1535/95 S-1 amino acid similarity values were lower compared with those of the other four RT-PCR Ark-positive field isolates (93.4%-94.8%), Ark DPI (91.9%), Ark 99 (93.0%), and Georgia var (88.7%). Furthermore, the isolates could be distinguished from the Ark reference strains by a characteristic sequence polymorphism, a six-nucleotide deletion encoding amino acids 57 (Asp) and 58 (Asp) in hypervariable region 1 of S-1. On the basis of the VN and sequencing findings, isolates Ark/213/96, Ark/15C/96, Ark/1529/95, and Ark/1534/95 were considered to be a single subtype of the Ark serotype. The fifth isolate, Ark/1535/95, may constitute another subtype of the Ark serotype. Vaccination of SPF chickens with a high-titering commercially available live vaccine containing the Ark DPI strain provided solid protection (>90%) against challenge with the RT-PCR Ark-positive field isolates. Immunization of SPF chickens with Ark/213/96 produced 100% protection against challenge with the homologous strain, as well as isolates Ark/1535/95 and Ark 99 but lower levels of protection against Ark DPI (58%) and Georgia var (55%). Primers for RT-PCR were designed to distinguish between the Ark subtypes and the Ark reference strains on the basis of the characteristic six-nucleotide deletion identified in the S...
Proximal spinal muscular atrophy (SMA) is an early onset, autosomal recessive motor neuron disease caused by loss of or mutation in SMN1 (survival motor neuron 1). Despite understanding the genetic basis underlying this disease, it is still not known why motor neurons (MNs) are selectively affected by the loss of the ubiquitously expressed SMN protein. Using a mouse embryonic stem cell (mESC) model for severe SMA, the RNA transcript profiles (transcriptomes) between control and severe SMA (SMN2+/+;mSmn−/−) mESC-derived MNs were compared in this study using massively parallel RNA sequencing (RNA-Seq). The MN differentiation efficiencies between control and severe SMA mESCs were similar. RNA-Seq analysis identified 3,094 upregulated and 6,964 downregulated transcripts in SMA mESC-derived MNs when compared against control cells. Pathway and network analysis of the differentially expressed RNA transcripts showed that pluripotency and cell proliferation transcripts were significantly increased in SMA MNs while transcripts related to neuronal development and activity were reduced. The differential expression of selected transcripts such as Crabp1, Crabp2 and Nkx2.2 was validated in a second mESC model for SMA as well as in the spinal cords of low copy SMN2 severe SMA mice. Furthermore, the levels of these selected transcripts were restored in high copy SMN2 rescue mouse spinal cords when compared against low copy SMN2 severe SMA mice. These findings suggest that SMN deficiency affects processes critical for normal development and maintenance of MNs.
Recent advances in high-throughput DNA sequencing technologies have equipped biologists with a powerful new set of tools for advancing research goals. The resulting flood of sequence data has made it critically important to train the next generation of scientists to handle the inherent bioinformatic challenges. The North East Bioinformatics Collaborative (NEBC) is undertaking the genome sequencing and annotation of the little skate (Leucoraja erinacea) to promote advancement of bioinformatics infrastructure in our region, with an emphasis on practical education to create a critical mass of informatically savvy life scientists. In support of the Little Skate Genome Project, the NEBC members have developed several annotation workshops and jamborees to provide training in genome sequencing, annotation and analysis. Acting as a nexus for both curation activities and dissemination of project data, a project web portal, SkateBase (http://skatebase.org) has been developed. As a case study to illustrate effective coupling of community annotation with workforce development, we report the results of the Mitochondrial Genome Annotation Jamborees organized to annotate the first completely assembled element of the Little Skate Genome Project, as a culminating experience for participants from our three prior annotation workshops. We are applying the physical/virtual infrastructure and lessons learned from these activities to enhance and streamline the genome annotation workflow, as we look toward our continuing efforts for larger-scale functional and structural community annotation of the L. erinacea genome.
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