Beverly Dale

Vaccination against the cat flea Ctenocephalides felis felis.

Non‐chemical control of haematophagous parasites is a desirable goal. We report here on the use of concealed antigens from the major digestive organ of the cat‐flea as vaccine components. Rabbits were immunized with various antigens from cat flea midguts, and immunoglobulin from these rabbits was fed to cat fleas in an artifical feeding system. Antibody produced against soluble antigens from the midguts of fed fleas was able to kill fleas in this system. Dogs were then immunized with various antigen preparations, and challenged for a week with live fleas. Significantly fewer live fleas were recovered from dogs immunized with fed midgut supernatant, and recovered live female fleas produced significantly fewer eggs. This study indicates the possibility of vaccination as a means of control of flea, and possibly other blood sucking insect populations.

Analysis of the polypeptides synthesized in rinderpest virus-infected cells

We have identified, by [35S]methionine labeling, eight major induced proteins and a number of minor proteins in rinderpest virus-infected bovine kidney cells. The polypeptides ranged in molecular weight from 212 to 21.5 kDa. The majority of these polypeptides are virus specific, as demonstrated by immunoprecipitation with rabbit hyperimmune serum against rinderpest. Infected cells radiolabeled with glucosamine contained a 75-kDa polypeptide and a broad band migrating at 80 kDa, both identified as virus specific by immunoprecipitation. Phosphorylated virus-specific proteins of 65 kDa and a complex of polypeptides at 92.5 kDa were also identified. Monospecific and monoclonal antibodies against measles virus and canine distemper virus hemagglutinin, fusion protein, nucleocapsid protein, and phosphoproteins confirmed the identity of the corresponding rinderpest virus-specific polypeptides.

Direct and uninterrupted RNA amplification of enteroviruses with colorimetric microwell detection

BACKGROUND Enteroviruses (EV) cause a broad spectrum of human diseases, of which aseptic meningitis is among the most common and most clinically vexing. While the clinical symptoms of meningitis caused by bacteria, fungi and viruses are similar, the diagnosis, therapy and outcome of disease caused by these agents vary greatly. In order to appropriately manage meningitis patients, rapid and reliable diagnosis of EV meningitis impacts significantly on patient management. OBJECTIVE To develop a direct and uninterrupted RNA amplification of enteroviruses using rTth DNA polymerase. STUDY DESIGN Purified coxsackievirus B6 RNA of various concentrations was amplified by rTth DNA polymerase-mediated amplification to determine analytic sensitivity. The specificity of the EV amplification was examined with a panel of nucleic acids from 36 EV serotypes, 15 non-EV pathogens and 10 coded clinical specimens of cerebrospinal fluid (CSF). RESULTS All EV serotypes tested were detected successfully by this method at a sensitivity of 1 TCID(50) with the exception of echoviruses 1, 5, 22 and 23. Echovirus 5 was detected at 10 TCID(50), and echovirus 1 was detected at 100 TCID(50). Echoviruses 22 and 23 were not detectable at 100 TCID(50). Cross-reactivity of EV RT-PCR assay with 15 known non-EV meningitis pathogens has not been observed. Results of 10 CSF tested with this system correlated well with tissue culture. CONCLUSIONS We have developed an EV amplification assay which has several important advantages over previously reported methods. This assay employs rTth DNA polymerase which possesses both reverse transcriptase and DNA polymerase activities, simplifying RNA reverse transcription and DNA amplification to an uninterrupted reaction. Additionally, potential carryover contamination and enhanced amplification specificity is provided by substituting dUTP for dTTP and adding uracil N-glycosylase (UNG) in the amplification reaction. Finally, the detection of amplified product is via a colorimetric, microwell format permitting the use of readily available instrumentation.

Nucleotide Sequence of the Inter-Structural Gene Region of Feline Infectious Peritonitis Virus

The sequence of the region located between the S and M glycoprotein genes of the 79-1146 strain of feline infectious peritonitis virus (FIPV) is presented. The inter-structural gene region encodes 3 open reading frames (ORFs), termed ORFs 3a, 3b and 4, with nucleotide sequences conforming to the minimum conserved transcription signal upstream of each. An additional ORF, 3x, partially overlaps the 3′ end of ORF 3a. The FIPV interstructural gene region is identical in length when compared to the Insavc-1 strain of canine coronavirus (CCV) but differs from various strains of transmissible gastroenteritis virus (TGEV) by the presence of deletions and insertions. The sizes of ORF 3a and 4 are conserved in FIPV, TGEV and CCV. However, as with CCV, the FIPV ORF 3b is truncated in comparison with TGEV.