Genetic Analyses of "Paranoiac" Mutants of PARAMECIUM TETRAURELIA

Six mutants of Paramecium tetraurelia with curious "Paranoiac" phenotypes have been isolated and examined. Instead of the normal transient avoiding reactions in Na⁺ solutions, these mutants show "violent avoidances"—backing continuously for 10 to over 60 sec. This behavior corresponds to prolonged membrane excitation.—Genetic analyses establish five genic loci at which mutations give the "Paranoiac" phenotype. Close linkage between two of these genes occurs. Allelic variants are found for two of the genes. In one case, the two alleles determine very different behavioral phenotypes ("Paranoiac" and "fast-2"). These results show that the mechanism(s) which shuts off excitation in the wild-type membrane is (are) complex, but in the future may be fruitfully pursued in mutants which are defective.     

Drosophila Vesicular Monoamine Transporter Mutants Can Adapt to Reduced or Eliminated Vesicular Stores of Dopamine and Serotonin

Physiologic and pathogenic changes in amine release induce dramatic behavioral changes, but the underlying cellular mechanisms remain unclear. To investigate these adaptive processes, we have characterized mutations in the Drosophila vesicular monoamine transporter (dVMAT), which is required for the vesicular storage of dopamine, serotonin, and octopamine. dVMAT mutant larvae show reduced locomotion and decreased electrical activity in motoneurons innervating the neuromuscular junction (NMJ) implicating central amines in the regulation of these activities. A parallel increase in evoked glutamate release by the motoneuron is consistent with a homeostatic adaptation at the NMJ. Despite the importance of aminergic signaling for regulating locomotion and other behaviors, adult dVMAT homozygous null mutants survive under conditions of low population density, thus allowing a phenotypic characterization of adult behavior. Homozygous mutant females are sterile and show defects in both egg retention and development; males also show reduced fertility. Homozygotes show an increased attraction to light but are mildly impaired in geotaxis and escape behaviors. In contrast, heterozygous mutants show an exaggerated escape response. Both hetero- and homozygous mutants demonstrate an altered behavioral response to cocaine. dVMAT mutants define potentially adaptive responses to reduced or eliminated aminergic signaling and will be useful to identify the underlying molecular mechanisms.     

Lmo mutants reveal a novel role for circadian pacemaker neurons in cocaine-induced behaviors

Drosophila has been developed recently as a model system to investigate the molecular and neural mechanisms underlying responses to drugs of abuse. Genetic screens for mutants with altered drug-induced behaviors thus provide an unbiased approach to define novel molecules involved in the process. We identified mutations in the Drosophila LIM-only (LMO) gene, encoding a regulator of LIM-homeodomain proteins, in a genetic screen for mutants with altered cocaine sensitivity. Reduced Lmo function increases behavioral responses to cocaine, while Lmo overexpression causes the opposite effect, reduced cocaine responsiveness. Expression of Lmo in the principal Drosophila circadian pacemaker cells, the PDF-expressing ventral lateral neurons (LN_vs), is sufficient to confer normal cocaine sensitivity. Consistent with a role for Lmo in LN_v function, Lmo mutants also show defects in circadian rhythms of behavior. However, the role for LN_vs in modulating cocaine responses is separable from their role as pacemaker neurons: ablation or functional silencing of the LN_vs reduces cocaine sensitivity, while loss of the principal circadian neurotransmitter PDF has no effect. Together, these results reveal a novel role for Lmo in modulating acute cocaine sensitivity and circadian locomotor rhythmicity, and add to growing evidence that these behaviors are regulated by shared molecular mechanisms. The finding that the degree of cocaine responsiveness is controlled by the Drosophila pacemaker neurons provides a neuroanatomical basis for this overlap. We propose that Lmo controls the responsiveness of LN_vs to cocaine, which in turn regulate the flies' behavioral sensitivity to the drug.     

Chromosomal Location of Pleiotropic Negative Sporulation Mutations in BACILLUS SUBTILIS

Genetic analysis by PBS-1 transduction and transformation of a large group of pleiotropic negative sporulation mutants has shown that mutations of this phenotype may be located in five genetically distinct regions. The first group of mutant sites, spoA mutations, is located in the terminal region of the chromosome and linked to the lys-1 marker by PBS-1 transduction. The second group, spoB mutations, is located between phe-1 and the attachment site for the lysogenic bacteriophage ϕ 105. Fine structure analysis of the mutant sites within the spoB locus has been accomplished. A third location for mutants of this phenotype, spoE mutants, was found between the metC3 and ura-1 markers. Two mutants were found at this site and both were capable of sporulation, in contrast to the rest of the pleiotropic sporulation mutants. A fourth chromosomal site, spoH mutations, was found near the ribosomal and RNA polymerase loci. A large group of mutant sites, spoF mutations, was found to be linked to each other by recombination index analysis in transformation but unlinked to any of the known auxotrophic mutations comprising the chromosomal map. All mutants analyzed showing a pleiotropic negative phenotype were found to map within one of these five regions. Interspecific transformation with Bacillus amyloliquefaciens as donor has shown that all of the pleiotropic negative sporulation mutations are conserved relative to a selected group of auxotrophic markers. The degree of conservation in decreasing order is: spoH > spoF = spoB > spoA.     

Behavioral and Biochemical Defects in Temperature-Sensitive Acetylcholinesterase Mutants of DROSOPHILA MELANOGASTER

Temperature-sensitive (ts) mutants of the Ace gene, which codes for acetylcholinesterase (AChE) in Drosophila melanogaster, were analyzed for defects in viability, behavior and function of the enzyme. The use of heat-sensitive and cold-sensitive mutations permited the function of AChE in the nervous system to be analyzed temporally. All ts mutations were lethal, or nearly so, when animals expressing them were subjected to restrictive temperatures during late embryonic and very early larval stages. Heat treatments to Ace-ts mid- and late larvae had little effect on the behavior of these animals or on the viability or behavior of the eventual adults. Heat-sensitive mutants exposed to nonpermissive temperatures as pupae, by contrast, had severe defects in phototaxis and locomotor activity as adults. AChE extracted from adult ts mutants that had developed at a permissive temperature were abnormally heat labile, and they had reduced substrate affinity when assayed at restrictive temperatures. However, enzyme activity did not decline during exposure of heat-sensitive adults to high temperatures even though such treatments caused decrements in phototaxis (29°) and, eventually, cessation of movement (31°). The cold-sensitive mutant also produced readily detectable levels of AChE when exposed to a restrictive temperature during the early developmental stage when this mutation causes almost complete lethality. We suggest that the relationship among the genetic, biochemical and neurobiological defects in these mutants may involve more than merely temperature-sensitive catalytic functions.     

Macoilin, a conserved nervous system-specific ER membrane protein that regulates neuronal excitability

Genome sequence comparisons have highlighted many novel gene families that are conserved across animal phyla but whose biological function is unknown. Here, we functionally characterize a member of one such family, the macoilins. Macoilins are characterized by several highly conserved predicted transmembrane domains towards the N-terminus and by coiled-coil regions C-terminally. They are found throughout Eumetazoa but not in other organisms. Mutants for the single Caenorhabditis elegans macoilin, maco-1, exhibit a constellation of behavioral phenotypes, including defects in aggregation, O₂ responses, and swimming. MACO-1 protein is expressed broadly and specifically in the nervous system and localizes to the rough endoplasmic reticulum; it is excluded from dendrites and axons. Apart from subtle synapse defects, nervous system development appears wild-type in maco-1 mutants. However, maco-1 animals are resistant to the cholinesterase inhibitor aldicarb and sensitive to levamisole, suggesting pre-synaptic defects. Using in vivo imaging, we show that macoilin is required to evoke Ca²⁺ transients, at least in some neurons: in maco-1 mutants the O₂-sensing neuron PQR is unable to generate a Ca²⁺ response to a rise in O₂. By genetically disrupting neurotransmission, we show that pre-synaptic input is not necessary for PQR to respond to O₂, indicating that the response is mediated by cell-intrinsic sensory transduction and amplification. Disrupting the sodium leak channels NCA-1/NCA-2, or the N-,P/Q,R-type voltage-gated Ca²⁺ channels, also fails to disrupt Ca²⁺ responses in the PQR cell body to O₂ stimuli. By contrast, mutations in egl-19, which encodes the only Caenorhabditis elegans L-type voltage-gated Ca²⁺ channel α1 subunit, recapitulate the Ca²⁺ response defect we see in maco-1 mutants, although we do not see defects in localization of EGL-19. Together, our data suggest that macoilin acts in the ER to regulate assembly or traffic of ion channels or ion channel regulators.     

Deletion of the Bombyx mori odorant receptor co-receptor (BmOrco) impairs olfactory sensitivity in silkworms

Olfaction plays an essential role in many important insect behaviors such as feeding and reproduction. To detect olfactory stimuli, an odorant receptor co-receptor (Orco) is required. In this study, we deleted the Orco gene in the Lepidopteran model insect, Bombyx mori, using a binary transgene-based clustered regulatory interspaced short palindromic repeats (CRISPR)/Cas9 system. We initially generated somatic mutations in two targeted sites, from which we obtained homozygous mutants with deletion of a 866 base pair sequence. Because of the flight inability of B. mori, we developed a novel method to examine the adult mating behavior. Considering the specialization in larval feeding, we examined food selection behavior in Orco somatic mutants by the walking trail analysis of silkworm position over time. Single sensillum recordings indicated that the antenna of the homozygous mutant was unable to respond to either of the two sex pheromones, bombykol or bombykal. An adult mating behavior assay revealed that the Orco mutant displayed a significantly impaired mating selection behavior in response to natural pheromone released by a wild-type female moth as well as an 11:1 mixture of bombykol/bombykal. The mutants also exhibited a decreased response to bombykol and, similar to wild-type moths, they displayed no response to bombykal. A larval feeding behavior assay revealed that the Orco mutant displayed defective selection for mulberry leaves and different concentrations of the volatile compound cis-jasmone found in mulberry leaves. Deletion of BmOrco severely disrupts the olfactory system, suggesting that BmOrco is indispensable in the olfactory pathway. The approach used for generating somatic and homozygous mutations also highlights a novel method for mutagenesis. This study on BmOrco function provides insights into the insect olfactory system and also provides a paradigm for agroforestry pest control.     

Co-transmission of neuropeptides and monoamines choreograph the C. elegans escape response

Co-localization and co-transmission of neurotransmitters and neuropeptides is a core property of neural signaling across species. While co-transmission can increase the flexibility of cellular communication, understanding the functional impact on neural dynamics and behavior remains a major challenge. Here we examine the role of neuropeptide/monoamine co-transmission in the orchestration of the C. elegans escape response. The tyraminergic RIM neurons, which coordinate distinct motor programs of the escape response, also co-express the neuropeptide encoding gene flp-18. We find that in response to a mechanical stimulus, flp-18 mutants have defects in locomotory arousal and head bending that facilitate the omega turn. We show that the induction of the escape response leads to the release of FLP-18 neuropeptides. FLP-18 modulates the escape response through the activation of the G-protein coupled receptor NPR-5. FLP-18 increases intracellular calcium levels in neck and body wall muscles to promote body bending. Our results show that FLP-18 and tyramine act in different tissues in both a complementary and antagonistic manner to control distinct motor programs during different phases of the C. elegans flight response. Our study reveals basic principles by which co-transmission of monoamines and neuropeptides orchestrate in arousal and behavior in response to stress.     

Closely linked lesions in a region of the X chromosome affect central and peripheral steps in gustatory processing in Drosophila

Summary We have analyzed a set of closely linked mutations on the X chromosome of Drosophila that lead to defects in gustatory behavior. The mutations map to a small region of the X chromosome between 10E1–4. Two distinct complementation groups, gustB and gustD, map to the ends of this region. These groups show complex complementation patterns with the mutations gustC and GT-1, which also map to this region. We describe the behavioral and electrophysiological properties of the mutants. These mutations affect peripheral receptor properties as well as more central processing steps in the gustatory pathway.     

Genetic Analyses of Heat-Sensitve Pawn Mutants of PARAMECIUM AURELIA

Heat-sensitive Pawn (ts Pawns) of Paramecium aurelia behaved normally when grown at 23° but failed to avoid strong stimuli at 35°. Four of the five ts Pawn lines tested were found to be allelic at a locus known also to carry temperature-independent Pawn mutations. The fifth ts Pawn line complemented all the conditional and unconditional Pawn mutants of the two known loci. This result, together with the patterns of F₂ segregation from various crosses, suggested the existence of a third Pawn locus. An additive effect of the unlinked ts Pawn genes was observed. These findings and the significance of ts Pawns as experimental material in behavioral and physiological research are discussed.     

Behavioral Mutants of DROSOPHILA MELANOGASTER. II. Behavioral Analysis and Focus Mapping

Several simple tests have been applied to study the behavior and performance of mutants of Drosophila melanogaster isolated in the preceding study (Homyk and Sheppard 1977). The tests showed that many mutants have specific behavioral abnormalities and that most mutants can easily be distinguished from an Oregon-R control on the basis of their behavioral phenotypes. Mutants representing six genes hop poorly and are unable to initiate wing oscillation when tethered. Mutations in four genes reduce the level of spontaneous motor activity of flies and increase the excitability threshold necessary to induce high activity motor functions such as running and flying. The latter mutants are referred to as hypoactive. Another class, stress-sensitive, including mutations in three genes, are reversibly paralyzed by mechanical shock. Mosaic analyses suggest that six mutations affect muscular tissue and two others affect neural tissue. It is also shown that tan mutants fail to retract their forelegs during flight and that the focus responsible for this behavioral phenotype is the compound eye. Specific behavioral abnormalities of several mutants are discussed in conjunction with previous studies from many laboratories concerning the participation of neural, sensory and muscular elements producing behavior in normal (nonmutant) insects. Such considerations are an essential prelude to anatomical and physiological studies of the mutants in Drosophila.     

CRISPR/Cas9 in rice can induce new mutations in later generations,leading to chimerism and unpredicted segregation of the targeted mutation

CRISPR/Cas9 is a novel tool for targeted mutagenesis and is applicable to plants, including rice. Previous reports on CRISPR/Cas9 in rice have demonstrated that target mutations are transmitted to the next generation in accordance with Mendelian law, but heritability of the target mutation and the role of inherited Cas9 gene have not been fully elucidated. Here, we targeted the rice phytoene desaturase gene, mutants of which exhibit an albino phenotype, by using CRISPR/Cas9 and analyzed segregation of target mutations. Agrobacterium-mediated methods using immature embryos successfully transformed a CRISPR/Cas9 system into five rice cultivars and subsequently induced mutation. Unpredicted segregations, with more mutants than theoretically predicted, were frequently found in T₁ plants from monoallelic T₀ mutants. Chimeric plants with both biallelic and monoallelic mutated cells were also observed in the T₁. Next, we followed segregation of a target mutation in the T₂ from monoallelic T₁ mutants. When T₁ mutants possessed Cas9, unpredicted segregations of the target mutation and chimeric plants were observed again in the T₂. When T₁ mutants did not possess Cas9, segregation of the target mutations followed Mendelian law and no chimeric plants appeared in the T₂. T₂ mutants with Cas9 had mutations different from the original ones found in T₀. Our results indicated that inherited Cas9 was still active in later generations and could induce new mutations in the progeny, leading to chimerism and unpredicted segregation. We conclude that Cas9 has to be eliminated by segregation in T₁ to generate homozygous mutants without chimerism or unpredicted segregation.     

Studies of opal mutations in bacteriophage T4B

Hydroxylamine-induced amber and opal mutants are localized on the map of gene 47 of bacteriophage T4B. The matched map of amber and opal mutations showed the presence of four paired sites which seemed to have arisen in the triplet coding for tryptophan.In growth studies o opal mutants in gene 47 in a series of Su⁺ strains the number of strains bearing a gene-suppressor for amber or ochre mutations also had a weak suppressor activity for some opal mutants. This suppressor acitivity is supposedly due to a second mutation in gene Su_uga.A comparative study of the phage yield with amber and opal mutations located in the same (paired) triplet in gene 47 has shown that the suppressor activity depends on the location of the mutant site along the gene.Experiments dealing with the induction of reversions by nitrous acid in amber and opal mutants with mutational sites located in the same triplet of gene 47 (mutant pairs) have shown the essential influence of the nucleotide sequence in the triplet on the frequency of induced reverse mutations at the given site.     

Respiratory-deficient Mutants in Saccharomyces lactis

Six independent ultraviolet-induced respiratory-deficient mutants (petites) of Saccharomyces lactis were isolated and characterized. Two possessed a normal cytochrome spectrum, another displayed an increased level of all the cytochromes, and three suffered from a partial or complete loss of one or more of the cytochromes a, b, c, and c₁. All of the mutants were segregational petites; none was vegetative. Determination of linkage relationships between mutants was restricted because matings between mutants, homozygous or heterozygous, for loci affecting cytochrome content were blocked at various stages in the mating-sporulating sequence. At least three of the petites were genetically nonidentical. Three of the mutations appeared to occupy loci within the same linkage group; two of the three mutations that mapped within this region were cytochrome-deficient. Growth at high or low temperatures, under increased osmotic pressure or in media supplemented with various fatty acids or sterols, did not relieve the physiological defects in these mutants. Reasons for the differences in survival of segregational and vegetative petites within this species are examined.     

A Genetic RNAi Screen for IP3/Ca2+ Coupled GPCRs in Drosophila Identifies the PdfR as a Regulator of Insect Flight

Insect flight is regulated by various sensory inputs and neuromodulatory circuits which function in synchrony to control and fine-tune the final behavioral outcome. The cellular and molecular bases of flight neuromodulatory circuits are not well defined. In Drosophila melanogaster, it is known that neuronal IP₃ receptor mediated Ca²⁺ signaling and store-operated Ca²⁺ entry (SOCE) are required for air-puff stimulated adult flight. However, G-protein coupled receptors (GPCRs) that activate intracellular Ca²⁺ signaling in the context of flight are unknown in Drosophila. We performed a genetic RNAi screen to identify GPCRs that regulate flight by activating the IP₃ receptor. Among the 108 GPCRs screened, we discovered 5 IP₃/Ca²⁺ linked GPCRs that are necessary for maintenance of air-puff stimulated flight. Analysis of their temporal requirement established that while some GPCRs are required only during flight circuit development, others are required both in pupal development as well as during adult flight. Interestingly, our study identified the Pigment Dispersing Factor Receptor (PdfR) as a regulator of flight circuit development and as a modulator of acute flight. From the analysis of PdfR expressing neurons relevant for flight and its well-defined roles in other behavioral paradigms, we propose that PdfR signaling functions systemically to integrate multiple sensory inputs and modulate downstream motor behavior.     

Morphological and sensorimotor phenotypes in a zebrafish CHARGE syndrome model are domain-dependent

CHARGE syndrome is a heterogeneous disorder characterized by a spectrum of defects affecting multiple tissues and behavioral difficulties such as autism, attention-deficit/hyperactivity disorder, obsessive–compulsive disorder, anxiety, and sensory deficits. Most CHARGE cases arise from de novo, loss-of-function mutations in chromodomain-helicase-DNA-binding-protein-7 (CHD7). CHD7 is required for processes such as neuronal differentiation and neural crest cell migration, but how CHD7 affects neural circuit function to regulate behavior is unclear. To investigate the pathophysiology of behavioral symptoms in CHARGE, we established a mutant chd7 zebrafish line that recapitulates multiple CHARGE phenotypes including ear, cardiac, and craniofacial defects. Using a panel of behavioral assays, we found that chd7 mutants have specific auditory and visual behavior deficits that are independent of defects in sensory structures. Mauthner cell-dependent short-latency acoustic startle responses are normal in chd7 mutants, while Mauthner-independent long-latency responses are reduced. Responses to sudden decreases in light are also reduced in mutants, while responses to sudden increases in light are normal, suggesting that the retinal OFF pathway may be affected. Furthermore, by analyzing multiple chd7 alleles we observed that the penetrance of morphological and behavioral phenotypes is influenced by genetic background but that it also depends on the mutation location, with a chromodomain mutation causing the highest penetrance. This pattern is consistent with analysis of a CHARGE patient dataset in which symptom penetrance was highest in subjects with mutations in the CHD7 chromodomains. These results provide new insight into the heterogeneity of CHARGE and will inform future work to define CHD7-dependent neurobehavioral mechanisms.     

Genetic Evidence for Physical Interactions between Enzymes of Nucleotide Synthesis and Proteins Involved in DNA Replication in Bacteriophage T4

We have found that mutations in phage T4 genes 41 (five of five) and 61 (three of three) cause resistance to the folate analogue pyrimethamine that inhibits T4 dihydrofolate (FH₂) reductase. These genes code for subunits of a T4 primase and are part of a putative T4 replication complex. In contrast to many previously isolated folate analogue-resistant (Far) T4 mutants, these T4 primase mutants do not overproduce FH₂ reductase nor do they alter its primary structure. A new mutant with a single lesion in gene 41 was isolated which proved resistant to the folate analogue at 30° and was lethal at 42°. This mutant induced normal levels of FH₂ reductase (encoded by the frd gene) and appeared to have normal expression of other T4 genes at 30°. Like other mutations in gene 41, tsP129 reduced phage-induced DNA synthesis to about 15% that of wild-type T4 as measured by thymidine incorporation under restrictive conditions. Double mutants carrying mutations in genes 41 and 61, 41 and frd or 61 and frd showed allele-specific suppression suggesting that the products of these genes interact. We suggest that abnormal interactions between components of the replication complex and a DNA precursor synthesizing complex cause folate analog resistance by allosterically altering the T4 FH₂ reductase.     

Isolation and Mapping of t Gene Mutants of Bacteriophage T4D

A procedure for selective isolation of T4 t mutants is described. At 120 min after infection of Escherichia coli cells with a low multiplicity of T4 bacteriophage, the mixture was sedimented through a linear sucrose gradient, and infected cells that remained intact were collected as the fastest sedimenting fraction. Ten to 50% of the phage released by chloroform treatment of this fraction were t mutants. Collection of a high proportion of t mutants depended on efficient elimination of cells that would survive because of superinfection lysis inhibition. This was accomplished by early addition of anti-T4 serum and heat-killed cells to inactivate progeny wild-type phage released at the normal burst time. Of 85 t mutants that were isolated and mapped, 23 new mutations were found, 14 of which are suppressible by an rII mutation and 9 of which are suppressible by rII or amber suppressors. Two hot-spot sites for spontaneous mutations were found; 14 mutants at one site, represented by a frameshift mutation, and 12 mutants at a second site were obtained from 39 spontaneous mutants independently isolated from different parental plaques. On our map of the t gene, the distance between the farthest t mutations is 6% recombination. A nonreverting triple t mutant, constructed to contain a frameshift mutation between two amber mutations, exhibited the same t mutant phenotype observed with revertible t mutants.