How important is the eggshell as a source for initial acquisition of Salmonella in hatchling turtles?

How and when turtles first acquire gut microflora is largely speculative. In this study, the eggshell and hatching process were evaluated for their role in the initial acquisition of Salmonella, by red-eared slider turtles (Trachemys scripta elegans). First, we examined whether the eggshell is a viable substrate for bacterial persistence during incubation, and if internal egg components (i.e., albumen, yolk, and embryo) have detectable bacterial loads. Second, we experimentally manipulated Salmonella by treating eggs with combinations of Salmonella and gentamicin, an effective Gram-negative antibiotic. We found that the eggshell is a viable substrate for maintaining bacteria, as well as an effective barrier to Salmonella transmission as internal egg components were largely bacteria-free. Water samples collected 18 days post-hatch from individuals that were experimentally inoculated with a topical application of Salmonella as eggs had a higher prevalence of Salmonella than those from eggs inoculated with Salmonella but topically treated with gentamicin prior to hatching, control eggs, and eggs only treated with gentamicin, but by day 35 post-hatch there were no detectable differences among the treatment groups. Though it can also act as a barrier that prevents the bacteria from infecting the embryo prior to hatching these findings suggest that the eggshell is a likely source of Salmonella infection in turtle hatchlings.

Transformation and electrophoretic karyotyping of Coniochaeta ligniaria NRRL30616.

Coniochaeta ligniaria NRRL30616 is an ascomycete that grows with yeast-like appearance in liquid culture. The strain has potential utility for conversion of fibrous biomass to fuels or chemicals. Furans and other inhibitory compounds in lignocellulosic biomass are metabolized by NRRL30616, facilitating subsequent microbial fermentation of biomass sugars. This study undertook initial characterization of the genetic system of C. ligniaria NRRL30616. Transformation using hygromycin as a dominant selectable marker was achieved using protoplasts generated by incubating cells in 1% (v/v) ß-mercaptoethanol, followed by cell wall-digesting enzymes. Thirteen chromosomes with an estimated total size of 30.1 Mb were detected in C. ligniaria. The GC content of chromosomal DNA and of coding regions from cDNA sequences were 49.2 and 51.9%, respectively. This study is the first report of genome size, electrophoretic karyotype, and transformation system for a member of the Coniochaetales.

Haemophilus influenzae type b strain A2 has multiple sialyltransferases involved in lipooligosaccharide sialylation.

The lipooligosaccharide (LOS) of Haemophilus influenzae contains sialylated glycoforms, and a sialyltransferase, Lic3A, has been previously identified. We report evidence for two additional sialyltransferases, SiaA, and LsgB, that affect N-acetyllactosamine containing glycoforms. Mutations in genes we have designated siaA and lsgB affected only the sialylated glycoforms containing N-acetylhexosamine. A mutation in siaA resulted in the loss of glycoforms terminating in sialyl-N-acetylhexosamine and the appearance of higher molecular weight glycoforms, containing the addition of phosphoethanolamine, N-acetylgalactosamine, and N-acetylneuraminic acid. Chromosomal complementation of the siaA mutant resulted in the expression of the original sialylated LOS phenotype. A mutation in lic3A resulted in the loss of sialylation only in glycoforms lacking N-acetylhexosamine and had no effect on sialylation of the terminal N-acetyllactosamine epitope. A double mutant in siaA and lic3A resulted in the complete loss of sialylation of the terminal N-acetyllactosamine epitope and expression of the higher molecular weight sialylated glycoforms seen in the siaA mutant. Mutation of lsgB resulted in persistence of sialylated glycoforms but a reduction in N-acetyllactosamine containing glycoforms. A triple mutant of siaA, lic3A, and lsgB contained no sialylated glycoforms. These results demonstrate that the sialylation of the LOS of H. influenzae is a complex process involving multiple sialyltransferases.