Assessing human germ-cell mutagenesis in the Postgenome Era: a celebration of the legacy of William Lawson (Bill) Russell.

Birth defects, de novo genetic diseases, and chromosomal abnormality syndromes occur in approximately 5% of all live births, and affected children suffer from a broad range of lifelong health consequences. Despite the social and medical impact of these defects, and the 8 decades of research in animal systems that have identified numerous germ-cell mutagens, no human germ-cell mutagen has been confirmed to date. There is now a growing consensus that the inability to detect human germ-cell mutagens is due to technological limitations in the detection of random mutations rather than biological differences between animal and human susceptibility. A multidisciplinary workshop responding to this challenge convened at The Jackson Laboratory in Bar Harbor, Maine. The purpose of the workshop was to assess the applicability of an emerging repertoire of genomic technologies to studies of human germ-cell mutagenesis. Workshop participants recommended large-scale human germ-cell mutation studies be conducted using samples from donors with high-dose exposures, such as cancer survivors. Within this high-risk cohort, parents and children could be evaluated for heritable changes in (a) DNA sequence and chromosomal structure, (b) repeat sequences and minisatellites, and (c) global gene expression profiles and pathways. Participants also advocated the establishment of a bio-bank of human tissue samples from donors with well-characterized exposure, including medical and reproductive histories. This mutational resource could support large-scale, multiple-endpoint studies. Additional studies could involve the examination of transgenerational effects associated with changes in imprinting and methylation patterns, nucleotide repeats, and mitochondrial DNA mutations. The further development of animal models and the integration of these with human studies are necessary to provide molecular insights into the mechanisms of germ-cell mutations and to identify prevention strategies. Furthermore, scientific specialty groups should be convened to review and prioritize the evidence for germ-cell mutagenicity from common environmental, occupational, medical, and lifestyle exposures. Workshop attendees agreed on the need for a full-scale assault to address key fundamental questions in human germ-cell environmental mutagenesis. These include, but are not limited to, the following: Do human germ-cell mutagens exist? What are the risks to future generations? Are some parents at higher risk than others for acquiring and transmitting germ-cell mutations? Obtaining answers to these, and other critical questions, will require strong support from relevant funding agencies, in addition to the engagement of scientists outside the fields of genomics and germ-cell mutagenesis.

Transmission of mutations in the lacI transgene to the offspring of ENU-treated Big Blue male mice.

The purpose of the study was to determine: 1) if male germ cells of Big Blue mice carrying newly induced mutations in the lacI transgene were effective in fertilization; 2) if offspring arising from such mutant sperm had the mutation in germ cells and multiple somatic tissues; and 3) how the frequency of mutants induced in the lacI transgene compared to the frequency induced in endogenous genes traditionally employed to study germ cell mutagenesis in mice. Male B6C3F(1) mice hemizygous for the lambda/lacI transgene were treated weekly with 100 mg/kg body weight of the mammalian germ cell mutagen N-ethyl-N-nitrosourea (ENU). The cumulative dose for each treated animal was 300 mg ENU/kg body weight. Ten weeks later the treated mice were mated to T stock females and the resulting offspring were screened for specific-locus mutations at six loci affecting external appearance, as well as for mutations in the lacI transgene in multiple somatic tissues and germ cells. Five offspring carrying recessive specific-locus mutations were observed among 597 offspring screened (mutant frequency = 139.6 x 10(-5) per locus). Four offspring carrying lacI mutations were observed among 280 offspring screened (mutant frequency = 35.7 x 10(-5) per locus (assuming 40 target loci)). Each of the four lacI mutant offspring carried a different mutation. Three of the mutations were A:T-->G:C transitions and one a G:C-->A:T transition. Consistent with the expectation that a mutation induced in a parental germ cell and transmitted to a conceptus would exist in every cell of the offspring, each mutant mouse had identical mutations in all somatic tissues sampled, as well as in its germ cells. These data provide preliminary evidence for the biological validity of assessing induced, heritable mutations using transgenic mice, without the need for generating an F(1) generation.

Chlornaphazine and chlorambucil induce dominant lethal mutations in male mice.

Two antineoplastic agents, chlornaphazine (CN) and chlorambucil (CHL), were tested for the induction of dominant lethal mutations in male mice. Both compounds are nitrogen mustard derivatives and have been shown to be genotoxic in a variety of organisms. CN was administered intraperitoneally to DBA/2J male mice at a dosage of 0, 500, 1000, or 1500 mg/kg body weight (bw). Immediately following treatment, each male was mated at 4-day intervals to two virgin C57BL/6J females. CHL was administered intraperitoneally to C3H/HeJ and DBA/2J males at a dosage of 0, 2.5, or 5.0 mg/kg bw. These males were mated at weekly intervals to two virgin T-stock females. CN and CHL clearly induced dominant lethal mutations. CN induced dominant lethal effects in all post-meiotic germ-cell stages of treated DBA males, with a clear dose-response relationship. The results with CHL-treated DBA males indicated that all post-meiotic germ-cell stages, except late-spermatids, were affected by CHL treatment, while in C3H males, CHL induced dominant lethal effects in all post-meiotic germ-cell stages. A dose-response relationship was also observed with CHL in C3H male mice. In the present experiments, regardless of the agent or the mouse strain used, spermatids appeared to be the germ-cell stage most sensitive to dominant lethal induction.

Impact of acanthocephalan parasites on aggregation behavior of amphipods (Gammarus pseudolimnaeus).

Acanthocephalan parasites can manipulate the behavior of their amphipod intermediate hosts in ways that increase the amphipod's risk of being eaten by a predator that serves as the final host for the parasite. Some asocial amphipod species have been shown to increase the likelihood of aggregation in response to chemical cues associated with predators. If such aggregation has anti-predation benefits, it might be subject to manipulation by parasites. We tested this hypothesis by comparing the preference of parasitized and unparasitized amphipods (Gammarus pseudolimnaeus) for associating with a group of unparasitized conspecifics, both in the presence and absence of chemical cues from predatory brook sticklebacks (Culaea inconstans). Amphipods with encysted parasites (Corynosoma sp.) avoided aggregating, whereas unparasitized amphipods preferred to aggregate. We also found that the risk of predation by sticklebacks faced by an individual amphipod was significantly lower when the amphipod was in a group compared to when it was alone. This suggests that the aggregation response of unparasitized amphipods is an adaptive response to escape predation. This study provides evidence for a novel parasitic manipulation of intermediate host behavior that is likely to increase transmission to the definitive host.