Genetic analysis of instability inPetunia hybrida

Summary InPetunia hybrida frequent mutations of unstable alleles give rise to different types of periclinal chimeras. If genes expressed in the epidermis, such as the geneAn1 for flower colour, are concerned, mutations in the dermal layer of the shoot apex will result in changes in the phenotype but not in the offspring. Mutations in the subdermal layer will not lead to an altered phenotype, but to changes in the sporogenous tissues and, thus, to deviating segregations in progenies. Therefore, in crossing experiments with such an unstable mutant, it is always necessary to take the possibility into account that the plant may be a chimera, so as to prevent an incorrect interpretation of the recorded segregational ratios. Mutations of unstable alleles expressed in the mesophyll, such as geneYg3 for leaf colour, also give rise to chimeras. In such instances, however, a change in phenotype always involves a change in segregational ratios as well, since both the mesophyll and the sporogenous tissues are derived from the subdermal layer of the shoot apex.     

Dense cataract and microphthalmia (<Emphasis Type="Italic">dcm</Emphasis>) in BALB/c mice is caused by mutations in the <Emphasis Type="Italic">GJA8</Emphasis> locus

A spontaneous mutation in BALB/c mice that causes congenital dense cataract and microphthalmia (dcm) was reported previously. This abnormality was found to be inheritable and the mode of inheritance indicated that this phenotype is due to mutation of an autosomal recessive gene. We performed genetic screen to identify the underlying mutations through linkage analysis with the dcm progenies of F₁ intercross. We identified the region of mutation on chromosome 3 and further mapping and sequence analysis identified the mutation in the GJA8 gene that encodes for connexin 50. The mutation represents a single nucleotide change at position 64 (G to C) that results in a change in the amino acid glycine to arginine at position 22 (G22R) and is identical to the mutation previously characterized as lop10. However, the phenotype of these mice differ from that of lop10 mice and since it is one of the very few genetic models with recessive pattern of inheritance, we propose that dcm mice can serve as a useful model for studying the dynamics and interaction of the gap junction formation in mouse eye development.     

INTERFERENCE BETWEEN INDIVIDUALS IN PURE AND MIXED CULTURES OF STEPHANOMERIA MALHEURENSIS AND ITS PROGENITOR

The diploid annual plants Stephanomeria exigua ssp. coronaria and S. malheurensis are related as progenitor and derivative. Stephanomeria malheurensis is known only from a single locality in eastern Oregon where it grows alongside (cohabits) its parent. Although the species are morphologically similar, they can be distinguished under uniform garden conditions by differences in root/shoot ratio, duration of rosette growth, branch structure and number of flower heads, seed weight, and other characters. The species were grown in pure and mixed cultures at several densities in two experiments to test the hypothesis that the distinctive phenotype of S. malheurensis could have evolved to reduce competition with its parent. The experiment revealed that the expression of the S. malheurensis phenotype did not change when it was grown alone or in mixed cultures with ssp. coronaria. Stephanomeria malheurensis neither gained nor lost an advantage. Since the measured characters related directly to fitness components, this suggests that the phenotype of the derivative probably did not evolve as a result of character displacement brought about by interference with ssp. coronaria. The consequence of sympatry between a newly arisen species and its parent appears to depend on the nature of the environment at the time of its origin. In an open habitat such as the Oregon locality of S. malheurensis, competition with the progenitor need not be a primary factor influencing the evolution of a new species.     

PAR1b takes the stage in the morphogenetic and motogenetic activity of Helicobacter pylori CagA oncoprotein

Helicobacter pylori CagA oncoprotein is critically involved in gastric carcinogenesis. Upon delivery into gastric epithelial cells via type IV secretion, CagA induces an extremely elongated cell-shape known as the hummingbird phenotype, which is associated with massive changes in actin cytoskeleton and elevated motility. With the notion that the hummingbird phenotype reflects pathogenic/oncogenic activity of CagA, many studies have focused on the mechanism through which CagA induces the morphological change. Once delivered, CagA interacts with host proteins such as oncogenic phosphatase SHP2 and polarity-regulating kinase PAR1b. Whereas the essential role of the CagA-SHP2 interaction in inducing the hummingbird phenotype has been extensively investigated, involvement of the CagA-PAR1b interaction in the morphological change has remained uncertain. Recently, we found that the CagA-PAR1b interaction, which inhibits PAR1b kinase activity, influences the actin cytoskeletal system and potentiates the magnitude of the hummingbird phenotype. We also found that PAR1b inactivates a RhoA-specific GEF, GEF-H1, via phosphorylation and thereby inhibits cortical actin and stress fiber formation. Collectively, these findings indicate that CagA-mediated inhibition of PAR1b promotes RhoA-dependent actin-cytoskeletal rearrangement and thereby strengthens the hummingbird phenotype induced by CagA-stimulated SHP2 during infection with H. pylori cagA-positive strains.     

A non‐synonymous SNP in exon 3 of the KIT gene is responsible for the classic grey phenotype in alpacas (Vicugna pacos)

The alpaca classic grey phenotype is of particular interest to the industry. Until now, there were only indirect data suggesting that the KIT gene was involved in the classic grey phenotype. All exons of KIT in three black and three classic silvergrey alpacas were sequenced. Five non‐synonymous SNPs were observed. There was only one SNP found that was present only in the silvergrey alpacas, and this was also the only SNP predicted to be damaging. This variant results in a change of a glycine (Gly) to an arginine (Arg) at amino acid position 126 (c.376G>A), occurring in the second Ig‐like domain of the extracellular domain of KIT. Basic protein modelling predicted that this variant is likely destabilising. Therefore, an additional 488 alpacas were genotyped for this SNP using the tetra‐primer amplification refractory mutation system PCR (Tetra‐primer ARMS‐PCR). All classic grey alpacas were observed to be heterozygous, and 99.3% of non‐grey dark base colour alpacas were found to be homozygous for the wildtype allele in this position. These results confirm that the classic grey phenotype in alpacas is the result of a c.376G>A (p.Gly126Arg) SNP in exon 3 of KIT. These data also support the hypothesis that the grey phenotype is autosomal dominant and that the mutation is most likely homozygous lethal.     

Overexpression of the RADICAL-INDUCED CELL DEATH1 (RCD1) Gene of Arabidopsis Causes Weak rcd1 Phenotype with Compromised Oxidative-Stress Responses

rcd1 is a mutant of Arabidopsis thaliana that is more resistant to methyl viologen, but more sensitive to ozone than the wild type. rcd1-2 is caused by a single nucleotide substitution that results in a premature stop codon at Trp-332. The rcd1-2 mRNA level does not change significantly with the mutation. Since overexpression of rcd1-1 cDNA has been shown to bring about an rcd1-like phenotype, we created and examined the overexpression lines of RCD1 by the use of the cauliflower mosaic virus 35S promoter. The transgenic lines exhibited a weak rcd1-like phenotype, although no resistance to methyl viologen was observed. Further, they fully complemented the aberrant rcd1-2 phenotype. Subcellular localization of RCD1 was examined by transiently expressing green fluorescent protein (GFP) fused with RCD1 in onion epidermal cells. GFP signals are observed as aggregated foci in the inner nuclear matrix-like region.     

DETECTING CRYPTIC INDIRECT GENETIC EFFECTS

Indirect genetic effects (IGEs) occur when genes expressed in one individual alter the phenotype of an interacting partner. IGEs can dramatically affect the expression and evolution of social traits. However, the interacting phenotype(s) through which they are transmitted are often unknown, or cryptic, and their detection would enhance our ability to accurately predict evolutionary change. To illustrate this challenge and possible solutions to it, we assayed male leg‐tapping behavior using inbred lines of Drosophila melanogaster paired with a common focal male strain. The expression of tapping in focal males was dependent on the genotype of their interacting partner, but this strong IGE was cryptic. Using a multiple‐regression approach, we identified male startle response as a candidate interacting phenotype: the longer it took interacting males to settle after being startled, the less focal males tapped them. A genome‐wide association analysis identified approximately a dozen candidate protein‐coding genes potentially underlying the IGE, of which the most significant was slowpoke. Our methodological framework provides information about candidate phenotypes and candidate single‐nucleotide polymorphisms that underpin a strong yet cryptic IGE. We discuss how this approach can facilitate the detection of cryptic IGEs contributing to unusual evolutionary dynamics in other study systems.     

Constitutive Expression of Small Heat Shock Protein in an htpG Disruptant of the Cyanobacterium Synechococcus sp. PCC 7942

In cyanobacteria, a disruptant of hspA encoding a small heat shock protein homologue, shows decreased cell growth rates at moderately high temperatures, and loss of both basal and acquired thermo-tolerances, which resemble the phenotype of an htpG disruptant. In vitro studies have shown that both small heat shock protein and Hsp90 can bind and keep non-native proteins in a refolding-competent state under denaturing conditions. The aim of the present study is to elucidate whether constitutive expression of HspA can functionally replace HtpG, a prokaryotic homolog of Hsp90, in the cyanobacterium Synechococcus sp. PCC 7942. HspA did not improve the viability of the htpG disruptant at a lethal temperature, although it did that of the wild type. It did not improve an iron-starved phenotype of the mutant under normal growth conditions, a novel phenotype found in the present study. These results suggest that cellular function of HtpG may differ significantly from that of HspA.     

Origin and evolution of the waxy phenotype in Amaranthus hypochondriacus: evidence from the genetic diversity in the Waxy locus

The existence of polymorphism in the Waxy locus in a large gene pool of 53 strains with various waxy phenotypes from samples of Amaranthus hypochondriacus collected from different regions was investigated in an origin-and-evolution study. First, we screened all strains for a mutation point (G–A polymorphism in exon 6) by using PCR–RFLP and/or direct sequence analysis. The results showed that the nonsense mutation in the coding region (exon 6) of the Waxy gene was responsible for the change in perisperm starch, leading to a waxy phenotype in all strains. Second, phylogenetic analysis, which was based on the Waxy variation, indicated diverse waxy types occurring separately and independently in certain domesticated regions in Mexico. Finally, we designated nine molecular types by comparing obvious structural variations in the coding region of the Waxy gene. Among the molecular types, A. hypochondriacus contained Type III in three subtypes with the waxy phenotype, with evolutionary routes that could originate from Type II in accordance with G–A polymorphism. In addition, these types had the same mutation points by which the Waxy gene was converted into the waxy phenotype. Therefore, the present results showed that the nonsense mutation is a unique event in the evolution of waxy phenotypes in this crop. This study will provide useful information for understanding the evolutionary process of the waxy phenotype.     

An erythromycin process improvement using the diethyl methylmalonate-responsive (Dmr) phenotype of the <Emphasis Type="BoldItalic">Saccharopolyspora erythraea mutB</Emphasis> strain

The Saccharopolyspora erythraea mutB knockout strain, FL2281, having a block in the methylmalonyl-CoA mutase reaction, was found to carry a diethyl methylmalonate-responsive (Dmr) phenotype in an oil-based fermentation medium. The Dmr phenotype confers the ability to increase erythromycin A (erythromycin) production from 250–300% when the oil-based medium is supplemented with 15 mM levels of this solvent. Lower concentrations of the solvent stimulated proportionately less erythromycin production, while higher concentrations had no additional benefit. Although the mutB strain is phenotypically a low-level erythromycin producer, diethyl methylmalonate supplementation allowed it to produce up to 30% more erythromycin than the wild-type (control) strain—a strain that does not show the Dmr phenotype. The Dmr phenotype represents a new class of strain improvement phenotype. A theory to explain the biochemical mechanism for the Dmr phenotype is proposed. Other phenotypes found to be associated with the mutB knockout were a growth defect and hyper-pigmentation, both of which were restored to normal by exposure to diethyl methylmalonate. Furthermore, mutB fermentations did not significantly metabolize soybean oil in the presence of diethyl methylmalonate. Finally, a novel method is proposed for the isolation of additional mutants with the Dmr phenotype.     

Density‐dependent prophylaxis in primary anti‐parasite barriers in the velvetbean caterpillar

1. Organisms rely on a set of primary barriers to prevent invasion by parasites, and secondary defences to fight parasites that breach the primary barriers. However, maintaining these defences to be active and effective is costly. Thus, hosts increase investment in anti‐parasite defences under situations of high risk of infection and reduce defences when the risk is reduced (the ‘Density‐Dependent Prophylaxis’ hypothesis). 2. In the present study, it was tested whether the midgut primary defences of the velvetbean caterpillar Anticarsia gemmatalis Hübner present density‐dependent plasticity, and also whether these defences could be induced by a viral pathogenic challenge. The aim was to examine whether morphometry and the structure of the midgut and peritrophic matrix (PM) change in accordance with colour transition in caterpillars, and whether such changes may provide the caterpillars a more protective barrier against invasion by Anticarsia gemmatalis multiple nucleopolyhedrovirus (AgMNPV). 3. It was found that PM and the midgut epithelium of the velvetbean caterpillar change plastically according to phenotype, itself a response to changes in population density. Caterpillars reared at high densities (black phenotype) had a considerably thicker midgut epithelia and peritrophic matrices than those reared individually (green phenotype), and there was also more chitin in the PM of the former. 4. This was interpreted as the first demonstration of increased investment in primary, barrier, defences against parasites, in response to increased conspecific density and an increased risk of infection. The possibility that this arises as a positive result of pleiotropy is discussed further, wherein the biochemical pathways responsible for the up‐regulation of the immune system are also involved in midgut properties.     

UBE3A“mutations” in two unrelated and phenotypically different Angelman syndrome patients

Angelman syndrome (AS) is a rare neurodevelopmental disorder. Recently, several mutations have been found in the E6-AP ubiquitin protein ligase gene (UBE3A) in a group of patients who are nondeleted and do not have uniparental disomy or imprinting defects. Most of the reported mutations cluster within exons 9 or 16 of the UBE3A gene, and nearly all are predicted to give rise to truncated E6-AP ligases. Here, we describe two AS patients with dissimilar phenotypes. At the molecular level, they are both nondeleted, do not display uniparental disomy, and have normal imprint patterns. One has the typical AS phenotype and carries the previously reported 1344delAG de novo mutation involving a functionally significant region of UBE3A. The other expresses an atypical phenotype in that she has less severe ataxia, no inappropriate laughing, or epilepsy, and her EEG was normal at an early age. A 14-bp deletion in the 3’ untranslated region of exon 16 (3’UTRdel14) adjacent to the poly(A) signal was identified. Further investigation revealed that the DNA change was a neutral polymorphism. Haplotype analysis indicated that both the AS patient and her normal sibling had inherited the same maternal UBE3A gene and its 5’ flanking region. Although the 14-bp change has no functional significance, it assists with counseling to determine future risks of recurrence in this family. Received: 4 November 1997 / Accepted: 8 January 1998     

Growth consequences of plasticity of plant traits in response to light conditions

Summary We present a method for quantifying the growth advantage, if any, that results from the plasticity of plant traits in response to growth in high vs. low resource levels. The method, which uses two phenotypes and two resource levels, quantifies the average advantage that a phenotype has, in its own set of conditions, over the other phenotype. The method is applied to the growth of two phenotypes of Abutilon theophrasti, induced by high and low light intensity, in response to two levels of incident light intensity. We calculated the growth advantage first using relative growth rate, and second using whole-plant photosynthetic assimilation rate, as the response variable. Then we used the photosynthetic responses to changes in light intensity to calculate changes in growth rates of each phenotype when exposed to a change in light conditions. These three quantifications of growth advantage broadly agree with one another. Despite the great plasticity of its traits induced by growth in high vs. low light intensity, whole-plant plasticity did not allow Abutilon theophrasti to exhibit a significant growth advantage under these conditions. Indeed, the relative growth rate of the low light phenotype greatly exceeded that of the high light phenotype in high incident light conditions. This may have resulted from the higher leaf area ratio of the low light phenotype. Furthermore, the high light phenotype had significantly greater transpiration rate in both light conditions. For these reasons we suggest that light-induced plasticity of traits in Abutilon theophrasti may confer advantage in response to the variation in vapor pressure deficit that is associated with variation in light intensity. Light-induced plasticity may also be advantageous because under high incident light conditions the high-light phenotype has greater reproductive allocation than the low-light phenotype.     

Genetic regions that interact with loss- and gain-of-function phenotypes of <Emphasis Type="Italic">deltex</Emphasis> implicate novel genes in <Emphasis Type="Italic">Drosophila</Emphasis> Notch signaling

The Notch signaling pathway is an evolutionarily conserved mechanism that regulates many cell fate decisions. The deltex (dx) gene encodes an E3-ubiquitin ligase that binds to the intracellular domain of the Notch protein and regulates Notch signaling in a positive manner. However, it is still not clear how Dx does this. We generated a transgenic line, GMR-dx, which overexpresses dx in the developing Drosophila eye disc. The GMR-dx line showed a rough-eye phenotype, specific transformation of a photoreceptor cell (R3 to R4), and a rotation defect in the ommatidia. This phenotype was suppressed in combination with a dx loss-of-function mutant, indicating that it was due to a dx gain-of-function. We previously reported that overexpression of Dx results in the stabilization of Notch in late endosomes. Here, we found that three motifs in Dx, a region that binds to Notch, a proline-rich motif and a RING-H2 finger, were required for this stabilization, although the relative activity of these variants in this assay did not always correspond to the severity of the rough-eye phenotype. In an attempt to identify novel genes of the Notch pathway, we tested a large collection of chromosomal deficiencies for the ability to modify the eye phenotypes of the GMR-dx line. Twelve genomic segments that enhanced the rough-eye phenotype of GMR-dx were identified. To evaluate the specificity of these interactions, we then determined whether the deletions also interacted with the wing phenotypes associated with a loss-of-function mutation of dx, dx²⁴. Analyses based on whole-genome information allowed us to conclude that we have identified two novel loci that probably include uncharacterized genes involved in Dx-mediated Notch signaling.     

Developmental and genetic mosaic analysis of Drosophila m-dy mutants: Tissue foci for behavioral and morphogenetic defects

Mutants of the Drosophila miniature-dusky (m-dy) gene complex display morphogenetic phenotypes (miniature or dusky) caused by a change in the size and/or shape of the epidermal cells comprising the adult wing. In addition to a dusky phenotype, certain Andante-type mutants also exhibit lengthened circadian periods for two different behavioral rhythms. If the latter phenotype results from a direct effect on the circadian pacemaker, the Andante function should be required within the brain. In order to define the tissues that require the morphogenetic and behavioral functions, we have carried out a genetic mosaic analysis. This study demonstrates that normal wing morphogenesis is entirely dependent on the genotype of wing cells. Furthermore, temperature-shift experiments with a temperature-sensitive dy mutant indicate that the morphogenetic function is required during adult development, and after the cessation of wing epidermal cell proliferation. At this time in development, a columnar epithelium in the developing wing becomes flattened into the mature wing blade, and we postulate that the cell-size defect of m-dy mutants results from an alteration of this mor-phogenetic process. In contrast to the wing mor-phogenesis phenotype, the characterization of locomotor activity in mosaic adults revealed a strong correlation between the head genotype and the Andante circadian-period phenotype. This result indicates that neural tissues mediate the rhythm function. Thus, the behavioral and morphogenetic functions require gene expression in distinct tissues. Furthermore, the behavioral results are consistent with a requirement for Andante function within circadian pacemaker neurons. © 1995 Wiley-Liss, Inc.     

The human cytochrome c oxidase assembly factors SCO1 and SCO2 have regulatory roles in the maintenance of cellular copper homeostasis

Human SCO1 and SCO2 are metallochaperones that are essential for the assembly of the catalytic core of cytochrome c oxidase (COX). Here we show that they have additional, unexpected roles in cellular copper homeostasis. Mutations in either SCO result in a cellular copper deficiency that is both tissue and allele specific. This phenotype can be dissociated from the defects in COX assembly and is suppressed by overexpression of SCO2, but not SCO1. Overexpression of a SCO1 mutant in control cells in which wild-type SCO1 levels were reduced by shRNA recapitulates the copper-deficiency phenotype in SCO1 patient cells. The copper-deficiency phenotype reflects not a change in high-affinity copper uptake but rather a proportional increase in copper efflux. These results suggest a mitochondrial pathway for the regulation of cellular copper content that involves signaling through SCO1 and SCO2, perhaps by their thiol redox or metal-binding state.     

In vivo levels of mitochondrial hydrogen peroxide increase with age in mtDNA mutator mice

In mtDNA mutator mice, mtDNA mutations accumulate leading to a rapidly aging phenotype. However, there is little evidence of oxidative damage to tissues, and when analyzed ex vivo, no change in production of the reactive oxygen species (ROS) superoxide and hydrogen peroxide by mitochondria has been reported, undermining the mitochondrial oxidative damage theory of aging. Paradoxically, interventions that decrease mitochondrial ROS levels in vivo delay onset of aging. To reconcile these findings, we used the mitochondria‐targeted mass spectrometry probe MitoB to measure hydrogen peroxide within mitochondria of living mice. Mitochondrial hydrogen peroxide was the same in young mutator and control mice, but as the mutator mice aged, hydrogen peroxide increased. This suggests that the prolonged presence of mtDNA mutations in vivo increases hydrogen peroxide that contributes to an accelerated aging phenotype, perhaps through the activation of pro‐apoptotic and pro‐inflammatory redox signaling pathways.     

The role of the miR399-<Emphasis Type="Italic">PHO2</Emphasis> module in the regulation of flowering time in response to different ambient temperatures in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

A moderate change in ambient temperature significantly affects plant physiology including flowering time. MiR399 and its target gene PHOSPHATE 2 (PHO2) are known to play a role in the maintenance of phosphate homeostasis. However, the regulation of flowering time by the miR399-PHO2 module has not been investigated. As we have previously identified miR399 as an ambient temperature-responsive miRNA, we further investigated whether a change in expression of the miR399-PHO2 module affects flowering time in response to ambient temperature changes. Here, we showed that miR399b-overexpressing plants and a loss-of-function allele of PHO2 (pho2) exhibited an early flowering phenotype only at normal temperature (23°C). Interestingly, their flowering time at lower temperature (16°C) was similar to that of wild-type plants, suggesting that alteration in flowering time by miR399 and its target PHO2 was seen only at normal temperature (23°C). Flowering time ratio (16°C/23°C) revealed that miR399b-overexpressing plants and pho2 mutants showed increased sensitivity to ambient temperature changes. Expression analysis indicated that expression of TWIN SISTER OF FT (TSF) was increased in miR399b-overexpressing plants and pho2 mutants at 23°C, suggesting that their early flowering phenotype is associated with TSF upregulation. Taken together, our results suggest that miR399, an ambient temperature-responsive miRNA, plays a role in ambient temperature-responsive flowering in Arabidopsis.     

Gain of deleterious function causes an autoimmune response and Bateson–Dobzhansky–Muller incompatibility in rice

Reproductive isolation plays an important role in speciation as it restricts gene flow and accelerates genetic divergence between formerly interbreeding population. In rice, hybrid breakdown is a common reproductive isolation observed in both intra and inter-specific crosses. It is a type of post-zygotic reproductive isolation in which sterility and weakness are manifested in the F₂ and later generations. In this study, the physiological and molecular basis of hybrid breakdown caused by two recessive genes, hbd2 and hbd3, in a cross between japonica variety, Koshihikari, and indica variety, Habataki, were investigated. Fine mapping of hbd2 resulted in the identification of the causal gene as casein kinase I (CKI1). Further analysis revealed that hbd2-CKI1 allele gains its deleterious function that causes the weakness phenotype by a change of one amino acid. As for the other gene, hbd3 was mapped to the NBS-LRR gene cluster region. It is the most common class of R-gene that triggers the immune signal in response to pathogen attack. Expression analysis of pathogen response marker genes suggested that weakness phenotype in this hybrid breakdown can be attributed to an autoimmune response. So far, this is the first evidence linking autoimmune response to post-zygotic isolation in rice. This finding provides a new insight in understanding the molecular and evolutionary mechanisms establishing post-zygotic isolation in plants.     

Epithelial behaviors and threshold effects in the development and evolution of internal and external cheek pouches in rodents

The internal and external cheek pouches found in certain rodents arise early in development by an evagination of the buccal epithelium. Differences in the epithelial evaginations that produce the internal pouches of the Syrian hamster (Mesocricetus auratus) and least chipmunk (Eutamias minimus) are consistent with the view that they evolved independently. The external cheek pouches of rodents of the superfamily Geomyoidea represent a macroevolutionary phenotype when compared to the internal pouches of other rodents. Externalization of an internal pouch rudiment found in the geomyoids Dipodomys and Thomomys can be explained by a simple change early in its development, the effect of which is greatly magnified by facial growth. In this example, the traditional dichotomy between microevolutonary and macroevolutionary theories is bridged by an understunding of developmental dynamics.