silicon and Respiratory-Tract-Infections

Increasing demand for the low-cost production of valuable proteins has stimulated development of novel expression systems. Many challenges faced by existing technology may be overcome by using unicellular microalgae as an expression platform due to their ability to be cultivated rapidly, inexpensively, and in large scale. Diatoms are a particularly productive type of unicellular algae showing promise as production organisms. Here, we report the development of an expression system in the diatom Thalassiosira pseudonana by expressing the protective IbpA DR2 antigen from Histophilus somni for the production of a vaccine against bovine respiratory disease. The utilization of diatoms with their typically silicified cell walls permitted development of silicon-responsive transcription elements to induce protein expression. Specifically, we demonstrate that transcription elements from the silicon transporter gene SIT1 are sufficient to drive high levels of IbpA DR2 expression during silicon limitation and growth arrest. These culture conditions eliminate the flux of cellular resources into cell division processes, yet do not limit protein expression. In addition to improving protein expression levels by molecular manipulations, yield was dramatically increased through cultivation enhancement including elevated light and CO

Topics: Animals; Antibodies, Bacterial; Antigens, Bacterial; Bacterial Vaccines; Carbon Dioxide; Cattle; Cattle Diseases; Diatoms; Light; Mice; Pasteurellaceae; Pasteurellaceae Infections; Recombinant Proteins; Respiratory Tract Infections; Silicon; Transcription Factors; Vaccines, Synthetic

Nontypeable Haemophilus influenzae (NTHi) is a major cause of opportunistic respiratory tract infections, including otitis media and bronchitis. The persistence of NTHi in vivo is thought to involve bacterial persistence in a biofilm community. Therefore, there is a need for further definition of bacterial factors contributing to biofilm formation by NTHi. Like other bacteria inhabiting host mucosal surfaces, NTHi has on its surface a diverse array of lipooligosaccharides (LOS) that influence host-bacterial interactions. In this study, we show that LOS containing sialic (N-acetyl-neuraminic) acid promotes biofilm formation by NTHi in vitro and bacterial persistence within the middle ear or lung in vivo. LOS from NTHi in biofilms was sialylated, as determined by comparison of electrophoretic mobilities and immunochemical reactivities before and after neuraminidase treatment. Biofilm formation was significantly reduced in media lacking sialic acid, and a siaB (CMP-sialic acid synthetase) mutant was deficient in biofilm formation in three different in vitro model systems. The persistence of an asialylated siaB mutant was attenuated in a gerbil middle ear infection model system, as well as in a rat pulmonary challenge model system. These data show that sialylated LOS glycoforms promote biofilm formation by NTHi and persistence in vivo.

Topics: Acute Disease; Animals; Biofilms; Disease Models, Animal; Ear, Middle; Gerbillinae; Haemophilus Infections; Haemophilus influenzae; Lipopolysaccharides; Lung; Otitis Media; Rats; Rats, Sprague-Dawley; Respiratory Tract Infections; Sialic Acids; Silicon

Rapid, sensitive assays for nucleic acid amplification products have utility for the identification of bacterial or viral infections. We have developed a nucleic acid hybridization assay utilizing thin film technology that permits visual detection of hybrids. The silicon-based biosensor detects the presence of target sequences by enzymatically transducing the formation of nucleic acid hybrids into molecular thin films. These films alter the interference pattern of light on the biosensor surface, producing a perceived color change. We have applied this technology to the development of a chip containing capture probes specific for human respiratory virus sequences including respiratory syncytial virus, influenza virus A and B, parainfluenza virus types 1 and 3, and rhinovirus. In a ten-minute assay, the biosensor permits unambiguous identification of viral-specific RT/PCR products from infected cell lysates.

Topics: Base Sequence; Biosensing Techniques; Equipment Design; Humans; Nucleic Acid Hybridization; Oligonucleotide Probes; Respiratory Tract Infections; Reverse Transcriptase Polymerase Chain Reaction; Sensitivity and Specificity; Silicon; Viruses