Sub-chronic exposure to 1,1-dichloropropene induces frameshift mutations in lambda transgenic medaka

Subchronic perfluorooctanesulfonate (PFOS) exposure induces elevated mutant frequency in an in vivo λ transgenic medaka mutation assay

Perfluorooctanesulfonate (PFOS) has been widely detected in the environment, wildlife and humans, but few studies have ever examined its mutagenic effect in vivo. In the present study, we use a transgenic fish model, the λ transgenic medaka, to evaluate the potential mutagenicity of PFOS in vivo following a subchronic exposure of 30 days. The mutant frequency of cII target gene was 3.46 × 10^-5 in liver tissue from control fish, which increased by 1.4-fold to 4.86 × 10^-5 in fish exposed to 6.7 μg/L PFOS, 1.55-fold to 5.36 × 10^-5 in fish exposed to 27.6 μg/L PFOS, and 2.02-fold to 6.99 × 10^-5 in fish exposed to 87.6 μg/L PFOS. This dose-dependent increase of mutant frequency was also accompanied with mutational spectrum changes associated with PFOS exposure. In particular, PFOS-induced mutation was characterized by +1 frameshift mutations, which increased from 0% in control fish to 13.2% in fish exposed to 27.6 μg/L PFOS and 14.6% in fish exposed to 87.6 μg/L PFOS. Our findings provide the first evidence of PFOS's mutagenicity in an aquatic model system. Given the fact that most conventional mutagenic assays were negative for PFOS, we propose that PFOS-induced mutation in liver tissue of λ transgenic medaka may be mediated through compromised liver function.

No evidence for transgenerational genomic instability in the F1 or F2 descendants of Muta™Mouse males exposed to N-ethyl-N-nitrosourea

Exposure of male mice to genotoxic agents can increase mutation frequencies in their unexposed descendants. This phenomenon, known as transgenerational genomic instability (TGI), can persist for several generations. However, little is known about the underlying mechanisms. Chemically-induced TGI has been demonstrated in non-coding unstable tandem repeat DNA regions, but it is unclear whether it extends to other genetic endpoints. We investigated whether exposure of Muta™Mouse males to a single dose of 75mg/kg N-ethyl-N-nitrosourea (ENU) increased the spontaneous frequency of gene mutations or chromosome damage in their offspring. Treated males were mated with untreated females 3 days, 6 weeks or 10 weeks post-exposure to produce the F1 generation. Offspring were thus conceived from germ cells exposed to ENU as mature spermatozoa, dividing spermatogonia, or spermatogonial stem cells, respectively. F2 mice were generated by mating F1 descendants with untreated partners. Mutations in the lacZ transgene were quantified in bone marrow and micronucleus frequencies were evaluated in red blood cells by flow-cytometry for all F0 and their descendants. LacZ mutant frequencies were also determined in sperm for all exposed males and their male descendants. In F0 males, lacZ mutant frequencies were significantly increased in bone marrow at least 10-fold at all three time points investigated. In sperm, lacZ mutant frequency was significantly increased 7-11-fold after exposure of dividing and stem cell spermatogonia, but not in replication-deficient haploid sperm. Micronucleus frequencies assessed two days after ENU treatment were increased 5-fold in F0 males, but returned to control levels after 10 weeks. Despite the strong mutagenic response in F0 males, pre- and post-meiotic ENU exposure did not significantly increase lacZ mutant or micronucleus frequencies in F1 or F2 offspring. These findings suggest that TGI may not extend to all genetic endpoints and that further investigation of this phenomenon and its health relevance will require multiple measures of genomic damage.

Temporal and geographical genetic variation in the amphipod Melita plumulosa (Crustacea: Melitidae): Link of a localized change in haplotype frequencies to a chemical spill

Anthropogenic effects such as contamination affect the genetic structure of populations. This study examined the temporal and geographical patterns of genetic diversity among populations of the benthic crustacean amphipod Melita plumulosa in the Parramatta River (Sydney, Australia), following an industrial chemical spill. The spill of an acrylate/methacrylate co-polymer in naphtha solvent occurred in July 2006. M. plumulosa were sampled temporally between December 2006 and November 2009 and spatially in November 2009. Genetic variation was examined at the mitochondrial cytochrome c oxidase subunit I locus. Notably, nucleotide diversity was low and Tajima's D was significantly negative amongst amphipods collected immediately downstream from the spill for 10 months. We hypothesize that the spill had a significant localized effect on the genetic diversity of M. plumulosa. Alternate explanations include an alternate and unknown toxicant or a localized sampling bias. Future proposed studies will dissect these alternatives.

Isolated spermatozoa as indicators of mutations transmitted to progeny

Spermatozoa comprise a large and homogeneous population of cells that may serve as an alternative to resource-intensive assays of transmissible mutations based on progeny. To evaluate mutagenic responses in spermatozoa derived from germ cells exposed to a mutagen at different stages of spermatogenesis, we compared cII mutant frequencies (MFs) in spermatozoa collected from male lambda transgenic medaka exposed to ethylnitrosourea (ENU) as either post-meiotic or pre-meiotic germ cells. cII MFs in spermatozoa exposed to ENU as spermatogonial stem cells were induced significantly, 9-fold, compared to controls, whereas, cII MFs in spermatozoa exposed as spermatozoa/late spermatids were not elevated. To directly compare responses in spermatozoa with those in progeny, we analyzed cII MFs directly in spermatozoa and in the offspring produced from identical sperm samples of ENU-exposed males. cII MFs in isolated spermatozoa exposed to ENU as post-meiotic germ cells were not significantly elevated, whereas 11-30% of the progeny derived from the identically exposed germ cells exhibited significantly elevated cII MFs, approximately 2-fold to >130-fold, compared to controls. The contradictory responses between spermatozoa and progeny analyses can be attributed to induced pre-mutational lesions that remain intact in spermatozoa but were not detected as mutations. Progeny analyses, by contrast, revealed mutant individuals with elevated cII mutant frequencies because persistent DNA damage in the spermatozoa was fixed as mutations in cells of the early stage embryo. Spermatozoa exposed to a mutagen as spermatogonial stem cells can provide an efficient means to detect the portion of transmissible mutations that were fixed as mutations in spermatozoa. The caveat is that direct analyses of mutations in spermatozoa excludes the contribution of mutations that arise from post-fertilization processes in cells of early stage embryos, and therefore may underestimate the actual frequency of mutant offspring.

Transgenic lambda medaka as a new model for germ cell mutagenesis

To address the need for improved approaches to study mutations transmitted to progeny from mutagen-exposed parents, we evaluated lambda transgenic medaka, a small fish that carries the cII mutation target gene, as a new model for germ cell mutagenesis. Mutations in the cII gene in progeny derived from ethyl-nitrosourea (ENU)-exposed males were readily detected. Frequencies of mutant offspring, proportions of mosaic or whole body mutant offspring, and mutational spectra differed according to germ cell stage exposed to ENU. Postmeiotic germ cells (spermatozoa/late spermatids) generated a higher frequency of mutant offspring (11%) compared to premeiotic germ cells (3.5%). Individuals with cII mutant frequencies (MF) elevated more than threefold above the spontaneous MF (3 x 10(-5)) in the range of 10(-4) to 10(-3) were mosaic mutant offspring, whereas those with MFs approaching 1 x 10(-2) were whole body mutant offspring. Mosaic mutant offspring comprised the majority of mutant offspring derived from postmeiotic germ cells, and unexpectedly, from spermatogonial stem cells. Mutational spectra comprised of two different mutations, but at identical sites were unusual and characteristic of delayed mutations, in which fixation of a second mutation was delayed following fertilization. Delayed mutations and prevalence of mosaic mutant offspring add to growing evidence that implicates germ cells in mediating processes postfertilization that contribute to genomic instability in progeny. This model provides an efficient and sensitive approach to assess germ cell mutations, expands opportunities to increase understanding of fundamental mechanisms of mutagenesis, and provides a means for improved assessment of potential genetic health risks.