Isolation and evaluation of dextral-specific and dextral-enriched cDNA clones as candidates for the handedness-determining gene in a freshwater gastropod,<Emphasis Type="Italic"> Lymnaea stagnalis</Emphasis>

The handedness of gastropods is genetically determined. The freshwater gastropod Lymnaea stagnalis is a normally dextral species, but contains minor sinistral populations. The gene responsible for handedness determination in this species is predicted to function maternally and specifically in the dextral-ovipositing snail. In this study, we used differential screening and cDNA subtraction to isolate eight dextral genes that are specific to, or enriched in, the dextral-ovipositing strains of L. stagnalis. These genes were promising candidates for the handedness-determining gene. In order to determine whether the true handedness-determining gene was among them, we tested for genetic correlations between the level of expression of each dextral gene and the handedness phenotype, i.e., the chirality of the next generation offspring, by using a collection of backcross F₂ progeny of F₁ offspring from crosses between dextral and sinistral strains. Although the present study could not identify the handedness-determining molecules, this approach appears to be promising for the isolation of such developmentally important genes.Edited by N. Satoh     

Maternal effect of low temperature on handedness determination in C. elegans embryos

C. elegans embryos, larvae, and adults exhibit several left-right asymmetries with an invariant dextral handedness, which first becomes evident in the embryo at the 6-cell stage. Reversed (sinistral) handedness was not observed among > 10,000 N2 adults reared at 16°C or 20°C under standard conditions. However, among the progeny of adults reproducing at 10°C, the frequency of animals with sinistral handedness was increased to ∼0.5%. Cold pulse experiments indicated that the critical period for this increase was in early oogenesis, several hours before the first appearance of left-right asymmetry in the embryo. Hermaphrodites reared at 10°C and mated with males reared at 20°C produced sinistral outcross as well as sinistral self-progeny, indicating that the low temperature effect on oocytes was sufficient to cause reversals. Increased frequency of reversal was also observed among animals developed from embryos lacking the egg shell. Possible mechanisms for the control of embryonic handedness are discussed in the context of these results, including the hypothesis that handedness could be dictated by the chirality of a gametic component. © 1996 Wiley-Liss, Inc.     

Multiple reversals of chirality in the land snail genus Albinaria (Gastropoda,Clausiliidae)

Reversed chirality has frequently evolved in snails, although the vast majority coils dextrally. However, there are often sinistral species within a dextral genus or almost exclusively sinistral families, such as the Clausiliidae. Some populations of the predominantly sinistral clausiliid genus Albinaria, in the southern Greek mainland, coil dextrally. The origin, evolution and distribution of the dextral Albinaria are puzzling, and as there is no reliable phylogenetic reconstruction for this speciose genus, it remains unclear how many times a shift in chirality has really occurred. In this study, our aim was to elucidate the evolutionary pathways of dextrality in Albinaria. We undertook a molecular phylogenetic analysis of two mtDNA (16S and COI) and one nDNA marker (ITS1) and included dextral and sinistral representatives found in syntopy or not. Both mtDNA and nDNA tree topologies imply that dextrals did not evolve as a monophyletic lineage. Instead, dextral lineages have evolved from sinistral ancestors multiple times independently. The fragmented population structure in Albinaria facilitates genetic drift and contributes to fixation of the opposite chirality and overcoming of the mating disadvantage of left–right reversal. Stochastic phenomena and biogeographical barriers have trapped those reversals in a limited geographical area.     

Whole-body enantiomorphy and maternal inheritance of chiral reversal in the pond snail Lymnaea stagnalis

Sinistral and dextral snails have repeatedly evolved by left-right reversal of bilateral asymmetry as well as coiling direction. However, in most snail species, populations are fixed for either enantiomorph and laboratory breeding is difficult even if chiral variants are found. Thus, only few experimental models of chiral variation within species have been available to study the evolution of the primary asymmetry. We have established laboratory lines of enantiomorphs of the pond snail Lymnaea stagnalis starting from a wild population. Crossing experiments demonstrated that the primary asymmetry of L. stagnalis is determined by the maternal genotype at a single nuclear locus where the dextral allele is dominant to the sinistral allele. Field surveys revealed that the sinistral allele has persisted for at least 10 years, that is, about 10 generations. The frequency of the sinistral allele showed large fluctuations, reaching as frequent as 0.156 in estimate under the assumption of Hardy-Weinberg equilibrium. The frequency shifts suggest that selection against chiral reversal was not strong enough to counterbalance genetic drift in an ephemeral small pond. Because of the advantages as a model animal, enantiomorphs of L. stagnalis can be a unique system to study aspects of chirality in diverse biological disciplines.     

Fine Mapping of the Pond Snail Left-Right Asymmetry (Chirality) Locus Using RAD-Seq and Fibre-FISH

The left-right asymmetry of snails, including the direction of shell coiling, is determined by the delayed effect of a maternal gene on the chiral twist that takes place during early embryonic cell divisions. Yet, despite being a well-established classical problem, the identity of the gene and the means by which left-right asymmetry is established in snails remain unknown. We here demonstrate the power of new genomic approaches for identification of the chirality gene, “D”. First, heterozygous (Dd) pond snails Lymnaea stagnalis were self-fertilised or backcrossed, and the genotype of more than six thousand offspring inferred, either dextral (DD/Dd) or sinistral (dd). Then, twenty of the offspring were used for Restriction-site-Associated DNA Sequencing (RAD-Seq) to identify anonymous molecular markers that are linked to the chirality locus. A local genetic map was constructed by genotyping three flanking markers in over three thousand snails. The three markers lie either side of the chirality locus, with one very tightly linked (<0.1 cM). Finally, bacterial artificial chromosomes (BACs) were isolated that contained the three loci. Fluorescent in situ hybridization (FISH) of pachytene cells showed that the three BACs tightly cluster on the same bivalent chromosome. Fibre-FISH identified a region of greater that ∼0.4 Mb between two BAC clone markers that must contain D. This work therefore establishes the resources for molecular identification of the chirality gene and the variation that underpins sinistral and dextral coiling. More generally, the results also show that combining genomic technologies, such as RAD-Seq and high resolution FISH, is a robust approach for mapping key loci in non-model systems.     

Shell chirality in Cambrian gastropods and sinistral members of the genus <Emphasis Type="Italic">Aldanella</Emphasis> Vostokova, 1962

Shell chirality among Cambrian gastropods is discussed. It is demonstrated that the earliest members of the class include chiral aberrations with abnormal opposite coiling of the shell. It is assumed that, in Cambrian gastropods, speciation could have occurred by mutation in the locus determining the chirality, as is proposed for extant gastropods. In contrast to modern gastropods, the existence of chiral morphs within single species has not been recorded in Cambrian mollusks, whereas the presence of chiral twin species is possible. The systematic position of sinistral representatives of the genus Aldanella Vostokova, 1962 is considered. Aldanella golubevi sp. nov. with sinistral shell is described from the base of the Tommotian Stage of the Anabar Region. Aberrant sinistral specimens of the normally dextral species Aldanella utchurica Missarzhevsky in Rozanov et al., 1969 and Pelagiella adunca Missarzhevsky in Rozanov et al., 1969 are figured.     

Evolution of mirror images by sexually asymmetric mating behavior in hermaphroditic snails

Abstract Directionally asymmetric animals generally exhibit no variation in handedness of whole-body architecture. In contrast, reversed chirality in both coil and entire anatomy has frequently evolved in snails. We demonstrate a nonrandom pattern and deterministic process of chiral evolution, as predicted by the following hypothesis. Bimodal shell shapes are associated with discrete mating behaviors in hermaphroditic pulmonates. Flat-shelled species mate reciprocally, face-to-face. This sexual symmetry prevents interchiral mating because genitalia exposed by a sinistral on its left side cannot be joined with those exposed by a dextral on its right. Thus, selection against the chiral minority, resulting from mating disadvantage, stabilizes chiral monomorphism. Tall-shelled species mate nonreciprocally: the 'male' copulates by mounting the 'female's' shell, mutually aligned in the same direction. This sexual asymmetry permits interchiral copulation with small behavioral adjustments. Therefore, the positive frequency-dependent selection is relaxed, and reversal alleles persist longer in populations of tall-shelled species. We verified both the assumption and the prediction of this hypothesis: significantly lower interchiral mating success in a low-spired species and higher chiral evolution rate in high-spired taxa. Sexual asymmetry is the key to understanding the accelerated chiral evolution in high-spired pulmonates.     

Body handedness is directed by genetically determined cytoskeletal dynamics in the early embryo

Although substantial progress has been made recently in understanding the establishment of left-right asymmetry in several organisms, little is known about the initial step for any embryo. In gastropods, left-right body handedness is determined by an unknown maternally inherited single gene or genes at closely linked loci and is associated with the sense of spiral cleavage in early embryos. Contrary to what has been believed, we show that temporal and spatial cytoskeletal dynamics for the left- and right-handed snails within a species are not mirror images of each other. Thus, during the third cleavage of Lymnaea stagnalis, helical spindle inclination (SI) and spiral blastomere deformation (SD) are observed only in the dominant dextral embryos at metaphase-anaphase, whereas in the recessive sinistral embryos, helicity emerges during the furrow ingression. Actin depolymerization agents altered both cleavages to neutral. Further, we found a strong genetic linkage between the handedness-specific cytoskeletal organization and the organismal handedness, using backcrossed F4 congenic animals that inherit only 1/16 of dextral strain-derived genome either with or without the dextrality-determining gene(s). Physa acuta, a sinistral-only gastropod, exhibits substantial SD and SI levotropically. Thus, cytoskeletal dynamics have a crucial role in determination of body handedness with further molecular, cellular, and evolutionary implications.     

Dextral and sinistral <Emphasis Type="Italic">Amphidromus inversus</Emphasis> (Gastropoda: Pulmonata: Camaenidae) produce dextral sperm

Coiling direction in pulmonate gastropods is determined by a single gene via a maternal effect, which causes cytoskeletal dynamics in the early embryo of dextral gastropods to be the mirror image of the same in sinistral ones. We note that pulmonate gastropod spermatids also go through a helical twisting during their maturation. Moreover, we suspect that the coiling direction of the helical elements of the spermatozoa may affect their behaviour in the female reproductive tract, giving rise to the possibility that sperm chirality plays a role in the maintenance of whole-body chiral dimorphism in the tropical arboreal gastropod Amphidromus inversus (Müller, 1774). For these reasons, we investigated whether there is a relationship between a gastropod’s body chirality and the chirality of the spermatozoa it produces. We found that spermatozoa in A. inversus are always dextrally coiled, regardless of the coiling direction of the animal itself. However, a partial review of the literature on sperm morphology in the Pulmonata revealed that chiral dimorphism does exist in certain species, apparently without any relationship with the coiling direction of the body. Though our study shows that body and sperm chirality follows independent developmental pathways, it gives rise to several questions that may be relevant to the understanding of the chirality of spermatid ultrastructure and spermatozoan motility and sexual selection.     

Delayed prezygotic isolating mechanisms: evolution with a twist

Assortative mating characterizes the situation wherein reproducing individuals pair according to similarity. Usually, the impetus for this bias is attributed to some type of mate choice conferring benefits (e.g., increased fitness or genetic compatibility) and, thereby, promoting speciation and phenotypic evolution. We investigate, by computer simulation of an evolving deme-structured snail population, the ramifications ensuing from passive assortative mating wherein couples exhibiting opposite shell coil direction phenotypes experience a physical constraint on mating success: putative mating partners inhabiting stout dextral and sinistral shells are unable to exchange sperm. Because shell coil chirality genotype is encoded at a single locus by shell coil alleles that are inherited maternally, snails containing sinistral alleles can present the typical dextral phenotype. Consequently, the incidence of a sinistral allele in as few as one snail can be manifested as prezygotic reproductive isolation within a deme in a subsequent generation. However, because the efficacy of achieving this type of prezygotic reproductive isolation is affected by shell form, the likelihood and product of single-gene speciation should be determined by deme interaction (migration) and composition (morphological distribution). We test this hypothesis and show how stochastic migration interacts with passive assortative mating yielding morphologically induced prezygotic reproductive isolation to produce new species phenotypes. The results show that demes can achieve rapid macroscopic phenotypic transformation and indicate that sympatric speciation might be more plausible than naturalists recognize conventionally.     

The developmental genetics of dextrality and sinistrality in the gastropodLymnaea peregra

Summary The genetics of body asymmetry inLymnaea peregra follows a maternal mode of inheritance involving a single locus with dextrality being dominant to sinistrality. Maternal inheritance implies that all members of a brood have the same phenotype, however, some broods contain a few individuals of opposite coil. One purpose of this paper is to explain the origin of these anomalous individuals. Genetic analyses of sinistral broods with a few dextral individuals have led to the development of a cross-over model, with the anomalous dextrals originating as a consequence of crossing over either during meiosis or mitosis in the female germ line. The crossover either reconstitutes the dextral gene from previously dissociated parts, or creates a dextral gene by means of a position effect. The probability of a crossover event depends upon the appropriate combination of complementary sinistral chromosomes. Each crossover event has the potential of creating a unique dextral gene. Genetic analyses of dextral broods containing a few sinistral individuals have demonstrated that different dextral genes vary in penetrance.The dextral gene produces a product during oogenesis which influences the pattern of cleavage in the embryo; this cleavage pattern is translated into the appropriate body asymmetry. The other purpose of this paper is to provide an assay for this gene product. Cytoplasm from dextral eggs injected into uncleaved sinistral eggs causes these eggs to cleave in a dextral pattern. Cytoplasm from sinistral eggs has no effect on the cleavage pattern of dextral eggs. While the dextral gene product is made during oogenesis, it does not function in controlling cleavage until just before this process begins.     

The identification and characterization of a genetic marker linked to hypersensitivity to the cherry leafroll virus in walnut

Walnut blackline disease, caused by the walnut strain of the cherry leafroll virus, causes fatal necrosis of the graft union between susceptible, infected scions of Persian walnut (Juglans regia L.) and hypersensitive, resistant rootstocks. A backcross breeding program to transfer hypersensitivity to cherry leafroll virus from the Norther California black walnut (Juglans hindsii (Jeps.)), into Persian walnut was begun in 1987. Hypersensitivity to the virus is inherited as a single, dominant gene. The current procedures for identifying hypersensitive backcross progeny are slow and labor intensive. Bulks of DNA from backcrosses that were either hypersensitive or susceptible to cherry leafroll virus were compared using randomly amplified polymorphic DNA. One random decamer, sequence 5-CTCCTGCCAA-3 (OP-K15), produces a polymorphic fragment of about 720 bp that has about 7% recombination with hypersensitivity to cherry leafroll virus in our backcross populations. The polymorphic fragment was cloned and converted into a restriction fragment length polymorphism to demonstrate that it is a distinct, low-copy sequence.     

Cuticle chirality and body handedness in Caenorhabditis elegans

Caenorhabditis elegans adult animals exhibit an inherent chirality of fiber orientation in the basal layer of the cuticle, as well as a naturally invariant but experimentally reversible handedness in the left-right (L-R) asymmetry of the body plan. We have examined the relationship between cuticle chirality and body handedness in normal and L-R reversed animals, using Roller (Rol) mutants and transmission electron microscopy to monitor cuticle properties. Rol phenotypes, several of which have been shown to result from mutations in cuticle collagen genes, are characterized by an invariant, allele-specific handedness in their direction of rolling. We show for several alleles that this direction is not affected by L-R reversal of the body plan. We further show, by electron microscopy, that the chiral orientation of cuticle fibers in animals with normal cuticle is not reversed by L-R body-plan reversal. We conclude that cuticle chirality must be established independently of body-plan handedness. The cues that establish cuticle chirality are still unknown, as are the causes for different rolling directions in different Roller mutants. We discuss the question of how cuticle chirality maintains its independence, and how the orientations of the fiber layers may be determined. Dev. Genet. 23:164–174, 1998. © 1998 Wiley-Liss, Inc.     

Chiral speciation in terrestrial pulmonate snails

On the basis of data in the literature, the percentages of dextral versus sinistral species of snails have been calculated for western Europe, Turkey, North America (north of Mexico), and Japan. When the family of Clausiliidae is represented, about a quarter of all snail species may be sinistral, whereas less than one per cent of the species may be sinistral where that family does not occur. The number of single-gene speciation events on the basis of chirality, resulting in the origin of mirror image species, is not closely linked to the percentage of sinistral versus dextral species in a particular region. Turkey is nevertheless exceptional by both a high percentage of sinistral species and a high number of speciation events resulting in mirror image species. Shell morphology and genetic background may influence the ease of chirality-linked speciation, whereas sinistrality may additionally be selected against by internal selection. For the Clausiliidae, the fossil record and the recent fauna suggest that successful reversals in coiling direction occurred with a frequency of once every three to four million years.     

Expression of exogenous fluorescent proteins in early freshwater pond snail embryos

We have for the first time succeeded in expressing in vitro-synthesized mRNAs in both the sinistral and the dextral Lymnaea stagnalis early embryos by microinjecting the mRNAs into the eggs before the first polar body stage. Translation of exogenous mRNA in developing embryos was confirmed by expressing various fluorescent proteins; mCherry, DsRed-Express, and enhanced green fluorescent protein. We have found that the protein expression derived from the introduced exogenous mRNA largely depends on the elapsed time after the microinjection and not on the developmental stage of injection, and also on the amount of injected mRNA. Developmental abnormalities were hardly observed. The first notable fluorescent signal was detected within 2–3 h after the injection while the embryos were still in uncleaved stage. Fluorescence gradually increased until 8–9 h and was stable up to 24 h. From these results, it is suggested that there is enough translation machinery necessary for early development and the translation of injected mRNA proceeds immediately and constantly in the early embryos. This is true for both the sinistral and dextral L. stagnalis embryos. Application of the developed method to other freshwater pond snails, dextral Lymnaea peregra, sinistral Physa acuta, and sinistral Indoplanorbis exustus revealed that their early expression mechanisms to be similar to that of L. stagnalis. Thus, in vitro-synthesized mRNA expression is expected to be important for the understanding of evolutional process and the molecular mechanism underlining the handedness determination in these freshwater snail embryos.     

用高代回交材料筛选与番茄耐冷性相关的RAPD分子标记

以番茄冷敏感品系T9801为轮回亲本,以耐冷品系T9806为供体亲本,经7代回交选择获得具有较强耐冷性且具有T9801遗传背景的高代回交株系,从高代回交株系及冷敏感亲本提取DNA,用280个随机引物进行RAPD扩增和多态性分析,筛选到一个与番茄耐冷性相关的RAPD分子标记（OPF14）。     

Linkage analysis of the Bcg gene on mouse chromosome 1. Identification of a tightly linked marker

We have mapped and determined the gene order of five cloned genes in the vicinity of the murine host resistance gene Bcg on mouse chromosome 1. For this, we have used a RFLP-type analysis in panels of 43 recombinant inbred strains, 3 congenic mouse strains, and 186 segregating backcross progeny derived from inbred strains of Bcgr and Bcgs genotypes. The Bcg alleles of segregating animals were established by in vivo infection with Mycobacterium bovis (Bacillus Calmette-Guérin) strain Montreal. Genomic DNA prepared from progenitor mouse strains was isolated, digested with restriction endonucleases, and analyzed by Southern blotting to identify strain-specific RFLP for each DNA marker tested. Among a number of DNA markers tested, Len2, Fn, Vil, Alpi, and Achrg were found to co-segregate with Bcg in mouse strains congenic for this locus. Detailed segregation analysis of the five markers and Bcg showed that Vil was extremely close to Bcg with no recombinant identified, whereas Fn and Len2 were located 4.5 and 9 cM proximal of Bcg, respectively. Alpi and Achrg mapped 5 and 5.5 cM distal from Bcg, respectively. Pedigree analysis in the recombinant inbred strains and backcross animals indicated the gene order: centromere-Len2-Fn-Vil,Bcg-Alpi-Achrg. The tightly linked Vil marker can now be used as an entry point in recombinant genomic DNA libraries to clone sequences overlapping Bcg. This group of five genes flanking Bcg on mouse chromosome 1 is precisely conserved on the telomeric end of the long arm of human chromosome 2q. Our results suggest that a likely location for a putative human homologue to the murine host resistance gene Bcg is the long arm of human chromosome 2 (2q32-qter).     

A locus for eosinophilia in the MES rat is on Chromosome 19

Matsumoto Eosinophilia Shinshu (MES) is a rat strain that spontaneously develops eosinophilia and eosinophil-related inflammatory lesions in many organs. We performed chromosomal mapping of the gene for eosinophilia by breeding backcross progeny. The onset of eosinophilia appeared to be delayed in the progeny compared with that in MES, with the prevalence of eosinophilia in the backcross progeny at 12 weeks of age being 22.5%. Genetic linkage analysis with marker loci indicated the major locus for eosinophilia was located at the end of the q arm region of Chromosome 19 (between D19Rat8 and telomere). The locus was denoted eosinophilia 1 (eos1). These data will form the basis for identification of the eos1 gene using a reverse genetic approach, which will hopefully lead to elucidation of the mechanisms involved in eosinophilia and eosinophilopoiesis.     

Molecular phylogeny of the land snail genus Alopia (Gastropoda: Clausiliidae) reveals multiple inversions of chirality

Whereas the vast majority of gastropods possess dextral shell and body organization, members of the Clausiliidae family are almost exclusively sinistral. Within this group a unique feature of the alpine genus Alopia is the comparable representation of sinistral and dextral taxa, and the existence of enantiomorph taxon pairs that appear to differ only in their chirality. We carried out a molecular phylogenetic study, using mitochondrial cytochrome c oxidase subunit I (COI) gene sequences, in order to find out whether chiral inversions are more frequent in this genus than in other genera of land snails. Our results revealed multiple independent inversions in the evolutionary history of Alopia and a close genetic relationship between members of the enantiomorph pairs. The inferred COI phylogeny also provided valuable clues for the taxonomic division and zoogeographical evaluation of Alopia species. The high number of inverse forms indicates unstable fixation of the coiling direction. This deficiency and the availability of enantiomorph pairs may make Alopia species attractive experimental models for genetic studies aimed at elucidating the molecular basis of chiral stability. © 2013 The Linnean Society of London     

Maps from two interspecific backcross DNA panels available as a community genetic mapping resource

We established two mouse interspecific backcross DNA panels, one containing 94 N2 animals from the cross (C57BL/6J × Mus spretus)F₁ × C57BL/6J, and another from 94 N2 animals from the reciprocal backcross (C57BL/6J × SPRET/Ei)F₁ × SPRET/Ei. We prepared large quantities of DNA from most tissues of each animal to create a community resource of interspecific backcross DNA for use by laboratories interested in mapping loci in the mouse. Initial characterization of the genetic maps of both panels has been completed. We used MIT SSLP markers, proviral loci, and several other sequence-defined genes to anchor our maps to other published maps. The BSB panel map (from the backcross to C57BL/6J) contains 215 loci and is anchored by 45 SSLP and 32 gene sequence loci. The BSS panel map (from the backcross to SPRET/Ei) contains 451 loci and is anchored by 49 SSLP loci, 43 proviral loci, and 60 gene sequence loci. To obtain a high density of markers, we used motif-primed PCR to fingerprint the panel DNAs. We constructed two maps, each representing one of the two panels. All new loci can be located with a high degree of certainty on the maps at current marker density. Segregation patterns in these data reveal several examples of transmission ratio distortion and permit analysis of the distribution of crossovers on individual chromosomes.