Association of concentrations of beta-carotene in plasma on pregnancy per artificial insemination and pregnancy loss in lactating Holstein cows.

The objective of this study was to determine the association of beta-carotene concentration in plasma at the moment of artificial insemination (AI) on pregnancy/AI in lactating Holstein cows. A total of 399 events from 364 lactating Holstein cows were enrolled in the trial (143 primiparous and 221 multiparous). All cows were assigned to a timed AI protocol based on estradiol and progesterone. Blood samples were collected at the moment of AI and at 24 and 31d post-AI (samples on 31 d post-AI were collected only from cows that were diagnosed pregnant). The BCS were recorded at the time of AI. Plasma beta-carotene was quantified from blood samples taken at the time of AI using a single step denaturation and extraction into a solvent, followed by measurement using a portable spectrophotometer. Pregnancy-associated glycoproteins (PAG) were analyzed in blood samples taken at 24 and 31 d post-AI of pregnant cows. Milk production was collected for the entire experimental period. Pregnancy diagnosis was performed by ultrasound 31 and 60 d post-AI. Data was analyzed using the MIXED and GLIMMIX procedures of SAS. Cows classified as thin (<2.75) tended to have lower concentration of beta-carotene at AI when compared with those classified as Moderate (≥3.00; 3.8 ±â€¯0.1 vs. 4.3 ±â€¯0.1 µg/mL; P = 0.09). Concentration of beta-carotene were greater in multiparous compared with primiparous (P < 0.01). There was no correlation between concentration of beta-carotene and milk production (r = 0.04; P = 0.10). When plasma beta-carotene was categorized in quartiles, cows in the 1st quartile had lower pregnancy/AI and higher pregnancy losses when compared with cows that were in the 2nd, 3rd and 4th quartile (pregnancy/AI = 19.2 ±â€¯4.5, 33.7 ±â€¯4.7, 36.9 ±â€¯5.0 and 39.8 ±â€¯5.4%, respectively; P = 0.05; pregnancy losses = 41.9 ±â€¯4.8, 20.4 ±â€¯3.7, 22.1 ±â€¯4.1, and 15.7 ±â€¯4.2%, respectively; P < 0.05). There was no association between concentrations of beta-carotene at AI and PAG at 24 d post-AI (P = 0.60). Cows with greater concentrations of beta-carotene at AI were more likely to have greater concentrations of PAG at 31 d post-AI (P < 0.01). In conclusion, the concentration of beta-carotene at AI was affected by BCS and parity. Cows with higher concentrations of plasma beta-carotene at AI had greater pregnancy/AI, lower pregnancy losses and greater concentrations of PAG at d 31 post-AI, suggesting it may be associated with placental function in lactating dairy cows.

Studies on naturally occurring infectious bursal disease viruses suggest that a single amino acid substitution at position 253 in VP2 increases pathogenicity.

Three classic IBDV strains were previously isolated from commercial layer chicken flocks and shown to be phylogenetically related to vaccine strains but pathogenic in susceptible chickens. In this study, their viral genomes were sequenced and compared to sequences of vaccines being used in those flocks. The vaccine strains examined were sequenced directly from the manufacturer and had identical genome segment B sequences. Compared to these vaccines, the GA-1, H-30 and CS-2-35 isolates each had one silent mutation in the gene that encodes VP1. Compared to the two vaccines used at the time CS-2-35 was isolated, the segment A sequence of CS-2-35 contained numerous nucleotide and amino acid mutations suggesting the CS-2-35 virus was not closely related to these vaccines. This virus however did have amino acid mutations in VP2 that are reported to be necessary for replication in cell culture and lacked two of the three amino acid mutations previously shown to be necessary for virulence. These data suggest that CS-2-35 was a descendant from an attenuated strain of IBDV. When the segment A genomic sequences of the GA-1 and H-30 viruses were compared to the vaccines being used in those flocks they were most closely related to the attenuated D78 vaccine strain. In genome segment A, three nucleotide mutations in GA-1 and four in H-30 were observed compared to the D78 classic vaccine. These nucleotide mutations caused one amino acid (H253N) change in the GA-1 virus and two amino acids (H253Q and G259D) were different in the H-30 virus. In addition, both the GA-1 and H-30 viruses had the amino acid G76 in VP2 that appears to be unique to the vaccine D78. The data suggest that GA-1 and H-30 are genetically related and have a common ancestor even though they were isolated from geographically distant flocks. The evidence also suggests that GA-1, H-30 and CS-2-35 could be reversions from attenuated vaccine viruses or by coincidence genetically resemble classic IBDV vaccines. It should be noted that some of the classic virus vaccines were not being used according to the manufacturer's recommendations at the time the GA-1, H-30 and CS-2-35 strains were isolated. Together, the molecular and pathogenicity data indicate that a single amino acid mutation from Histidine (H) to Glutamine (Q) or Asparagine (N) at position 253 in VP2 will markedly increase the virulence of an attenuated IBDV.

The use of gamma irradiation for the inactivation of infectious bursal disease viruses.

The maximum dosage of gamma irradiation approved by the U.S. Food and Drug Administration (FDA) for poultry is 3.0 kiloGrays (kGy). This treatment is designed to reduce bacterial contamination on uncooked poultry carcasses and meat products. The possible presence of infectious bursal disease virus (IBDV) on poultry postharvest has prompted some countries to study the risk associated with introducing nonnative strains of the virus from imported commodities. The goal of this study was to determine if this risk could be reduced using gamma irradiation to inactivate IBDV. At the dosage approved by the FDA, the titers of IBDV vaccine strains were reduced between 0 and 1 log10. Titers of the pathogenic IBDV strains tested were not reduced after the 3.0 kGy exposure. Furthermore, titers of pathogenic viral strains were not reduced following exposure up to 5.0 kGy. As the exposure to gamma irradiation increased, the titers of the vaccine strains decreased. At the maximum dosage tested (10 kGy), the 89/03 variant virus vaccine was completely inactivated. Titers of the three classic IBDV vaccine strains were reduced between 1.6-2.0 logs after the 10 kGy exposure; however, these viruses remained viable after this treatment. Gamma irradiation is not an effective intervention to reduce the risk of IBDV introduction via processed poultry.

Characterization of infectious bursal disease viruses from four layer flocks in the United States.

Twenty bursal samples were obtained from four infectious bursal disease virus (IBDV)-vaccinated layer flocks experiencing problems with immune suppression that was thought to be infectious bursal disease. All the samples were found to be positive for IBDV by reverse transcriptase polymerase chain reaction (RT-PCR). Restriction fragment length polymorphism analysis of the samples identified them as classic molecular group 3 and group 4 viruses. Two samples from each of the four flocks were sequenced, and within a flock, these sequences were identical; however, between flocks, some differences were observed. One virus from each of the four flocks was selected for further analysis. The VP2 hypervariable sequence region of samples GA-1, H-30, and CS-2-35 had nucleotide and amino acid similarities with the D78 and Vi Bursa G classic vaccines that were used in those flocks. The sequence of HPR-2 was similar to the Bursa Vac 4 vaccine used in that flock and the STC virulent classic IBDV strain. The deduced amino acid sequence of these isolates revealed that all the isolates had proline at position 222, which is characteristic of U.S. classic viruses. The phylogenetic analysis of these isolates on the basis of the VP2 hypervariable amino acid sequence clustered GA-1, H-30, and CS-2-35 with the D78 vaccine and HPR-2 with STC. The pathogenicity of these isolates was tested in specific-pathogen-free chickens. Bursa-body weight (B-BW) ratios and histopathologic lesion scores in the bursa were determined. Gross lesions were observed in the bursa, and the B-BW ratios of the birds infected with all four wild-type viruses were significantly different compared with the D78 vaccine and uninoculated control groups. Histopathology of the bursa from groups infected with GA-1, H-30, CS-2-35, and HPR-2 showed different degrees of follicular depletion and necrosis. A very slight lymphoid depletion was observed in the D78-infected group at 5 days postinoculation, and no microscopic lesions were observed in this group at 8 days postinoculation or at any time in the uninoculated control group. The bursa collected from the field virus and D78-infected birds at necropsy revealed the presence of IBDV via RT-PCR, and the VP-2 hypervariable nucleotide sequences of the GA-1, H-30, CS-2-35, HPR-2, and D78 samples were identical to the original viral isolates and vaccine, respectively.

Molecular characteristics of infectious bursal disease viruses from asymptomatic broiler flocks in Europe.

Infectious bursal disease virus (IBDV) exists in several different antigenic and pathogenic forms. The immune suppression caused by this virus in young chickens is not always associated with clinical signs of disease. The antigenic variant viruses originally described in the United States typically do not cause clinical signs of disease but can cause a marked immune suppression via the destruction of B lymphocytes. Using a reverse transcription-polymerase chain reaction (RT-PCR) assay we conducted a survey of asymptomatic broiler chicken flocks in Europe for IBDV. Restriction fragment length polymorphisms in the viral protein 2 (VP2) gene of four isolates from Spain and four isolates from France indicated they may be different from the classic and very virulent (vv) IBDV strains found throughout Europe. Nucleotide sequence and phylogenetic analysis of the hypervariable region of the VP2 gene indicated that all eight viruses were more similar to U.S. variant viruses than classic viruses. In two viruses, one from France and one from Spain, threonine was observed at amino acid position 222 and serine was found at position 254. These two substitution mutations are characteristic of Delaware variant viruses. In addition, all eight viruses had mutated amino acid position 318 from glycine to aspartic acid, another substitution mutation commonly found in U.S. variant viruses. Although importation restrictions prevented us from directly testing the antigenicity of these viruses, their nucleotide and predicted amino acid sequences suggest they could be antigenically distinctive compared to classic and vvIBDV commonly found in Europe. Confirmation of the presence of antigenic variant IBDV strains in Europe requires additional immunologic studies to elucidate the exact nature of the viral epitopes. Our data support the need for these immunologic studies.

Molecular epidemiology of infectious bursal disease viruses: distribution and genetic analysis of newly emerging viruses in the United States.

Genetic mutations in the genome of infectious bursal disease virus (IBDV) have resulted in antigenic and pathogenic variants that continue to cause disease in commercially reared chickens. The extent of the genetic diversity among IBDV strains circulating in the United States is unknown. This study was designed to identify newly emerging viruses infecting chickens on poultry farms experiencing immune suppression-related problems. Fifty IBDV-positive samples were identified from 273 bursa samples using a real-time reverse transcription-polymerase chain reaction (RT-PCR) assay. Mutation probes were designed to the hydrophilic B coding region of the VP2 gene. Six mutation probes used in this study were based on the nucleotide sequences of the Del-E, Bursine 2, D-78, STC, G6, and T1 IBDV strains. Following real-time RT-PCR, these mutation probes identified 11 of the 50 viruses in the melting temperature (Tm) analysis. The results indicated that the remaining 39 viruses had one or more nucleotide mutations compared with the six mutation probes in this region of the VP2 gene. Thirty-eight viruses were chosen for nucleotide sequence analysis across the hypervariable region of the VP2 gene. Within this group of 38 viruses, four were identified by the mutation probes and their nucleotide sequences confirmed that real-time RT-PCR data. In the remaining 34 viruses, nucleotide mutations were observed in as many as 8 of 23 nucleotides across the hydrophilic B epitope coding region. Furthermore, every amino acid position except one between 316 and 324 had at least one substitution mutation. Phylogenic analysis placed two of the 38 viruses sequenced on branches with classic viruses and the remaining 36 viruses were placed on four distinct branches. Branches 1 and 2 contained a majority of the viruses, which were distributed across most of the major poultry-producing states in the United States. These branches contained previously characterized variant IBDV strains. Viruses in branches 3 and 4 were confined to three states and did not contain any previously characterized IBDV strains.

Biodistribution and computed tomography blood-pool imaging properties of polyethylene glycol-coated iopromide-carrying liposomes.

RATIONALE AND OBJECTIVES: Surface-modified contrast-carrying liposomes potentially are useful as computed tomography (CT) blood-pool agents. The biodistribution and CT-imaging behavior of conventional as well as polyethylene glycol (PEG)-coated iopromide-carrying liposomes were tested. Two different types of PEG-ylated lipids were used to demonstrate possible differences. METHODS: Iopromide-containing liposomes were prepared by a continuous high-pressure extrusion method and subsequently PEG-ylated by simple mixing with either DSPE-PEG2000 or CHHS-PEG2000. The resulting liposomes were investigated in rats (biodistribution) and rabbits (imaging). RESULTS: Surface modification with CHHS-PEG consistently resulted in less effective stabilization of liposomes in the blood than with DSPE-PEG. In the biodistribution study, no significant differences in blood concentration could be found 1 hour after injection between the different formulations at a dose of 250 mg total iodine/kg body weight (approximately 500 mg lipid/kg). At this dose, the unmodified as well as the DSPE-PEG liposomes displayed prolonged blood circulation with CT density differences above 70 Hounsfield units (aorta) for up to 20 minutes (n = 1). CONCLUSIONS: DSPE-PEG-coated and unmodified liposomes proved to be useful for CT blood-pool imaging displaying favorable imaging properties. Future studies will have to demonstrate whether PEG-ylation offers diagnostic or toxicologic advantages over conventional vesicles in this indication.

Preparation and evaluation of lyophilized iopromide-carrying liposomes for liver tumor detection.

RATIONALE AND OBJECTIVES: The objective of the present investigation was to demonstrate a new method for the production of iopromide-carrying liposomes. We studied biodistribution and elimination behavior, as well as the computed tomography (CT) liver imaging properties. METHODS: Iopromide-containing liposomes were prepared by the ethanol evaporation method and subsequently lyophilized. The resuspended liposomes were tested in rats and rabbits. RESULTS: After resuspension, liposomes with a mean diameter of 467 +/- 66 nm and an encapsulation rate of 41.5 +/- 5.5% were obtained. In rats, a marked accumulation of liposomal iopromide was found in the liver and spleen. In rabbits, complete renal elimination of iopromide within 7 days was demonstrated. At a dose of 150 mg total iodine/kg, a small tumor (< 0.5 cm) could be detected in a VX-2-bearing rabbit. CONCLUSIONS: The ethanol evaporation method proved to be suitable for the reproducible large-scale manufacture of iopromide liposomes with high encapsulation. The resuspended liposomes displayed favorable biodistribution, elimination and imaging characteristics.