Genetic characterization of the secretory mutant MS-1 of Tetrahymena thermophila: vacuolarization and block in secretion of lysosomal hydrolases are caused by a single gene mutation.

The genetics and phenotypic features (light and electron microscopy) of a secretory mutant, MS-1 of Tetrahymena thermophila blocked in secretion of lysosomal acid hydrolases have been analyzed. Although blocked constitutively in secretion, MS-1 contains active lysosomal hydrolases in amounts equivalent to the wild type. The 3:1 segregation in F-2 in sib crosses and the 1:1 segregation in test crosses indicate that the block in secretion of lysosomal hydrolases is controlled by a recessive single gene locus termed sec. The sec allele of MS-1 proved also to be responsible for the highly vacuolarized phenotype the mutant developed when it was transferred from nutrient medium into buffers of low ionic strength. Deletion mapping by crossing MS-1 with nullisomic strains, all secreting lysosomal hydrolases at wild-type rates, was performed. The sec phenotype was expressed in monosomic-4 progeny only, indicating that the sec allele is located on chromosome 4 of T. thermophila.     

Genetic and biochemical properties of thialysine-resistant mutants of Saccharomyces cerevisiae

Three groups of lysine-excreting, thialysine-resistant mutants of Saccharomyces cerevisiae were derived from the wild-type strain (X2180) by mutagenic treatment and selected on the basis of a cross-feeding assay. Mutants MNNG2-9, MNNG2-27, MNNG2-39 and MNNG2-62 (group 1) exhibited a 2:2 segregation for thialysine resistance following mating with a wild-type strain and a lower than wild-type lysyl-tRNA synthetase activity; the thialysine-resistant phenotype was dominant in specific hybrids. Mutant MNNG2-2 (group II) was similar to group I mutants except that the thialysine-resistant phenotype was recessive in the hybrid. Mutant MNNG3-142 (group III) exhibited an irregular ratio of segregation of thialysine resistance and a significantly lower lysyl-tRNA synthetase activity; the thialysine-resistant phenotype was recessive in the hybrid. The growth of both group I and group III mutants was temperature-sensitive. The thialysine-resistant mutants exhibited pleiotropic properties including the increased production and excretion of lysine, thermosensitive growth and an impairment of lysyl-tRNA synthetase activity.     

Genetic characterization of the secretory mutant MS-1 of Tetrahymena thermophila: Vacuolarization and block in secretion of lysosomal hydrolases are caused by a single gene mutation

The genetics and phenotypic features (light and electron microscopy) of a secretory mutant, MS-1, of Tetrahymena thermophila blocked in secretion of lysosomal acid hydrolases have been analyzed. Although blocked constitu-tively in secretion, MS-1 contains active lysosomal hydrolases in amounts equivalent to the wild type. The 3:1 segregation in F-2 in sib crosses and the 1:1 segregation in test crosses indicate that the block in secretion of lysosomal hydrolases is controlled by a recessive single gene locus termed sec. The sec allele of MS-1 proved also to be responsible for the highly vacuolarized phenotype the mutant developed when it was transferred from nutrient medium into buffers of low ionic strength. Deletion mapping by crossing MS-1 with nullisomic strains, all secreting lysosomal hydrolases at wild-type rates, was performed. The sec phenotype was expressed in monosomic-4 progeny only, indicating that the sec allele is located on chromosome 4 of T. thermophila. © 1992 Wiley-Liss, Inc.     

Genetics of resistance to cotton leaf curl disease in Gossypium hirsutum L. under field conditions

One hundred and forty two cotton germplasm lines were screened for cotton leaf curl virus symptoms in field evaluations during 2003, 2004, and 2005. Fifty cross combinations involving 30 of these lines classified resistant or susceptible were used for inheritance study of the disease. All the F(1) plants of crosses involving resistant x resistant, resistant x susceptible, and susceptible x resistant parents were resistant, indicating dominant expression of the disease resistance and there were no maternal or cytoplasmic effects detected from reciprocal hybridization. In 22 crosses, 4 types of segregation patterns were obtained in the F(2) generations. A good fit for 15 (resistant):1 (susceptible), 13 (resistant):3 (susceptible), 9 (resistant):7 (susceptible) ratios indicated digenic control of the trait with duplicate dominant, dominant inhibitory, and duplicate recessive epistasis, respectively. Three-gene control with triplicate dominant epistasis was obtained in one of the crosses. This segregation pattern, however, needs further confirmation due to smaller population size. The absence of complementary gene action was obtained in 1 susceptible x susceptible and 27 resistant x resistant crosses as their F(1)s were susceptible and resistant, respectively, and F(2) generation lacked segregation.     

Genetic analysis of mutation sy2 which causes nonhomologous meiotic synapsis in chromosomes of diploid rye Secale cereale L

Partially nonhomologous (heterologous) synapsis of meiotic chromosomes in a spontaneous desynaptic mutant form of rye is determined by two recessive genes, sy2a and sy2b, that have independent expression and inheritance. The third gene, dominant inhibitor suppressing the mutant phenotype, has been revealed in hybrid combinations between sy2 mutants and lines segregating other meiotic mutants: sy10 (heterologous synapsis), sy1, and sy9 (asynapsis). All three genes determining desynapsis (sy2a, sy2b, and I) were shown to be nonallelic to monogenic mutations sy10, sy1, and sy9, inherited independently of them and expressed at later stages of prophase I than the sy10 gene. The possibility of modifying monogenic segregation of mutation sy2 by gametophyte selection for a locus linked to the gene expressed as sy2 at particular frequencies of recombination between this gene and selected locus is discussed.     

蛋用鹌鹑伴性羽色基因互作与连锁的关系

本研究首次发现了鹌鹑伴性羽基因的基因互作关系并进行了遗传验证.试验证明,鹌鹑的栗羽、黄羽和白羽是Z染色体上两个有连锁关系的基因座B/b和Y/y相互作用的结果.B和b为一对等位基因,不控制任何性状,只与色素的合成有关,B为有色基因,b为白化基因,B对b为显性;Y和y为另一对等位基因,分别控制栗羽和黄羽,Y对y为显性.栗羽和黄羽的表现取决于有色基因B的存在,B与Y相互作用产生栗羽,B与y相互作用产生黄羽,白羽是白化基因b对Y和y上位作用的结果.B/b和Y/y两基因座在雄性表现出一定的互换率,在雌性为完全连锁.这一研究补充和发展了以前人们对鹌鹑羽色伴性遗传的研究,为人们利用鹌鹑羽色进行自别雌雄配套系生产提供了重要的遗传学基础。 Abstract:The interaction of sex-linked gene for plumage color in quails was first discovered and identified by genetictest.It was proved that the phenotypic expressions of the maroon feather,the yellow feather and the white feather result from the interaction between B/b and Y/y loci in the Z-chromosome.The allele B and b have something to do with the composition of pigment in plumage and nothing to do with any relative characters,the coloured gene B is dominant to its albino allele b.The maroon and yellow feather constituted a pair of relative characters determined by a couple of alleles Y and y,the maroon feather was caused by a dominant allele Y,and the yellow feather caused by a recessive allele y.But the phenotypic expression of maroon and yellow was decided by the present of the coloured gene B in Z-chromosome,the maroon feather was the result of interaction between gene B and Y,the yellow feather was result of interaction between gene B and y.The white was caused by a recessive albino gene b which epistasis to gene Y and y.The incomplete linkage was present between B/b and Y/y in Z-chromosome in male and complete linkage in female.This research enriches and delelops the earlier studies of the sex-linked inheritance of plumage color.It provides an important genetic basis for the quail autosexing system production by means of plumage color.     

Meiosis in NEUROSPORA CRASSA. I. the Isolation of Recessive Mutants Defective in the Production of Viable Ascospores

A scheme has been devised for efficient isolation of recessive meiotic mutants of Neurospora crassa. These mutants were detected by their reduced fertility or by the abortion of ascospores. Their isolation involved the selection and screening of the strains arising from ascospores disomic (n + 1) for linkage group I (LG I), which bears the mating-type locus. These strains are self-fertile heterokaryons that contain two types of haploid nuclei of opposite mating types (A + a). Selfings of these strains are homozygous for genes on all linkage groups except LGI and therefore allow the expression of recessive mutants with an altered sexual cycle. Using this selection procedure, three classes of mutants were detected. In one class, mutants had an early block in perithecial development (class I), and in another mutants had altered perithecia, but apparently unaltered fertility (class III). No recessive mutants were observed and all mutants tested (eight of class I and two of class III) were expressed only when used as the maternal parent. A third mutant class displayed normal production of perithecia, but defective formation of asci (class IIA), or black ascospores (class IIB). Four of 13 class IIA mutants were analyzed, and two of them [asc(DL131) and asc (DL400)] were definitely recessive analysis of 10 of 13 class IIB mutants disclosed six recessive, mutually complementing mutants: ase(DL95), asc(DL243), asc(DL711), asc(DL879), asc(DL917m) and asc(DL961). Mutants asc(DL95), asc(DL243) and the previously studied mei-1 mutant (Smith 1975) complemented one another in crosses, but did not recombine. These may be alleles of the same gene, or they may comprise a gene cluster.     

Linkage relationships of recessive chlorophyll mutations inArabidopsis thaliana (L.)Heynh

A new method enabling to localize recessive alleles controling lethal embryonal or chlorophyll mutations in linkage groups has been devised and verified. The information on the linkage was obtained in B₁ in repulsion after the crosses with recessive visible markers representing the individual linkage groups. The distinction of four B₁ genotypes was achieved by means of Müller's embryotest. Altogether eight mutant alleles were localized. The allelesch 2411, ch 4062 andX 3 are carried by the first linkage group, the allelesM 33 andM 25 by the third and the allelech 1378 by the fourth linkage group. The mutant allelesch 42 andM 4–6–18 showed the linkage with the markers of the fifth and the sixth linkage groups simultaneously. The possibilities of further development and use of this method are discussed.     

Phenotypic Expression of rkn1-Mediated Meloidogyne incognita Resistance in Gossypium hirsutum Populations

The root-knot nematode Meloidogyne incognita is a damaging pest of cotton (Gossypium hirsutum) worldwide. A major gene (rkn1) conferring resistance to M. incognita was previously identified on linkage group A03 in G. hirsutum cv. Acala NemX. To determine the patterns of segregation and phenotypic expression of rkn1, F₁, F₂, F_2:3, BC₁F₁ and F_2:7 recombinant inbred lines (RIL) from intraspecific crosses between Acala NemX and a closely related susceptible cultivar Acala SJ-2 were inoculated in greenhouse tests with M. incognita race 3. The resistance phenotype was determined by the extent of nematode-induced root galling and nematode egg production on roots. Suppression of root galling and egg production was highly correlated among individuals in all tests. Root galling and egg production on heterozygous plants did not differ from the susceptible parent phenotype 125 d or more after inoculation, but were slightly suppressed with shorter screening (60 d), indicating that rkn1 behaved as a recessive gene or an incompletely recessive gene, depending on the screening condition. In the RIL, rkn1 segregated in an expected 1 resistant: 1 susceptible ratio for a major resistance gene. However, within the resistant class, 21 out of 34 RIL were more resistant than the resistant parent Acala NemX, indicating transgressive segregation. These results suggest that rkn1-based resistance in G. hirsutum can be enhanced in progenies of crosses with susceptible genotypes. Allelism tests and molecular genetic analysis are needed to determine the relationship of rkn1 to other M. incognita resistance sources in cotton.     

The gene for dominant white color in the pig is closely linked to ALB and PDGRFRA on chromosome 8.

White is a widespread coat color among domestic pig breeds and is controlled by an autosomal dominant gene I. The segregation of this gene was analyzed in a reference pedigree for gene mapping developed by crossing the European wild pig and a Large White domestic breed. The gene for dominant white color was shown to be closely linked to the genes for albumin (ALB) and platelet-derived growth factor receptor alpha (PDGFRA) on chromosome 8. An unexpected phenotype with patches of colored and white coat was observed among the F1 and F2 animals. The segregation data indicated that the phenotype was controlled by a third allele, denoted patch (Ip), most likely transmitted by one of the Large White founder animals. It is shown that the ALB, PDGFRA, I linkage group shares homologies with parts of mouse chromosome 5, human chromosome 4, and horse linkage group II, all of which contain dominant genes for white or white spotting. Candidate genes for the dominant white and patch mutations in the pig are proposed on the basis on these linkage homologies and the recent molecular definition of the dominant white spotting (W) and patch (Ph) mutations in the mouse.     

Preferential segregation of two allelic mutations for small leaf character in groundnut

Summary Two radiation induced small leaf mutants were isolated in a Spanish Improved variety of groundnut. Both had more than a 50% reduced leaflet size which was associated with an increased number of imparipinnate leaves in one mutant and light yellow flower colour in the other. Genetic studies demonstrated that both mutants were allelic and controlled by recessive factors. Phenotypic and genotypic segregation ratios indicated a lower frequency of mutants. This was attributed to preferential segregation in favour of normal leaf size. Marker genes controlling krinkle leaf, virescent and chlorina characters showed independent assortment in crosses with the small leaf mutants. Absence of assortment of associated mutant characters viz., small leaf and light yellow flower colour, generally indicated pleiotropic effects. However, monohybrid segregation for flower colour in the cross between the two small leaf mutants showed that the two characters were independently induced and hence attributed to close linkage and not pleiotropy.This project was partly aided by the IAEA Research Contract No. 1892     

Random segregation inNeurospora

Data from five-point crosses involving linkage group I and three-point crosses involving linkage groups VI and VII ofNeurospora crassa andN. sitophila have been analysed in order to detect the phenomena of polarized segregation and partial spindle overlap.The results clearly show absence of polarized segregation in both species. They further show that partial spindle overlap is a rare event if at all it occurs in the two species. The occurrence of a majority of either symmetrical or asymmetrical classes is a feature common to both species.     

Genetic Analysis of the Reciprocal Translocation T2(I;VIII) of Aspergillus Using the Technique of Mitotic Mapping in Homozygous Translocation Diploids

A UV-induced sulphite-requiring mutant (sD50) consistently shows mitotic linkage to groups I and VIII in haploids from heterozygous mapping diploids. This linkage was found to be due to a reciprocal translocation T2(I;VIII) which could not be separated from the sulphite requirement in about 100 tested progeny from heterozygous crosses, and both may well have been induced by the same mutational event. T2(I;VIII) is the first case of a reciprocal translocation in Aspergillus which showed meiotic linkages between markers of different linkage groups, and, in addition, involved chromosome arms containing markers suitable for complete mapping by the technique of mitotic recombination in homozygous translocation diploids.-Using various selective markers, haploid segregants and diploid crossovers of all possible types were isolated from homozygous translocation diploids. (1) Haploid segregants showed new linkage relationships in T/T diploids: all available markers of VIII now segregated as a group with the majority of the markers of I, except for the markers of the left tip of I. These formed a separate linkage group and are presumably translocated to VIII. (2) Diploid mitotic crossovers confirmed this information and showed that the orientation of the translocated segments was unchanged. These findings conclusively demonstrate that T2(I;VIII) is a reciprocal translocation due to an exchange of the left tip of group I with the long right arm of group VIII.-Since the position of the break on VIIIR was found to be at sD50 this marker could be used to map the break on IL by meiotic recombination in heterozygous crosses. In addition, such crosses showed reduced recombination around the breaks, so that it was possible to sequence markers which normally are barely linked.     

Somatic chimerism, genetic inheritance, and mapping of the fleshless berry (flb) mutation in grapevine (Vitis vinifera L.).

The fleshless berry (flb) mutation of grapevine (Vitis vinifera L. 'Ugni Blanc') impairs the differentiation and division of inner mesocarp cells responsible for flesh in grapevine berries. In order to study the inheritance of the mutation and to map the flb locus, 5 segregating populations were created. Progeny plants were classified as mutant or wild type by scoring for the presence of an ovary phenotype associated with the Flb- phenotype at anthesis. Phenotypic segregation revealed the involvement of a single dominant allele that was heterozygous in the original mutant. Through bulk segregant analysis, microsatellite (simple sequence repeat (SSR)) markers linked to the mutation were identified, and the flb locus was assigned to linkage group 18. The locus position was then refined by analyzing individual progeny and the segregation of SSR markers in the target region with the closest marker 5.6 cM distant from the flb locus. All progeny with the Flb- ovary phenotype differed from the original fleshless berry mutant in that no berries formed after anthesis. Our data suggest that the original mutant plant was a chimera with the mutated allele present in only 1 cell layer (L2 layer) of the ovary and berry.     

Genetic regulation on the black phenotype mutants of moth and pupa of Helicoverpa armigera (Lepidoptera: Noctuidae)

Genetic regulation on body color of a mutant strain, JBM of Helicoverpa armigera with black body color of pupae and adults, was investigated. Reciprocal crosses between JBM and JBW (a wild strain with yellow brown body color of pupae and adults) were used to determine the inheritance characteristics of body color. Analysis of the ratio of phenotype segregation from the F1 generation, F2 generation, F3 generation, BC1 (F1 x JBM) generation and F1 generation of BC1 indicated that the black body color was controlled by one recessive gene.     

Inheritance of apospory in bahiagrass,Paspalum notatum

Previous studies on the inheritance of aposporous apomixis in bahiagrass showed a wide range of segregation ratios in crosses involving sexual and aposporous apomictic plants. The F1 progenies were classified through a visual progeny test carried out on few F2 plants. The number of sexual F1s highly exceeded the apomictics leading to the conclusion that apomixis was controlled by a few recessive genes. The present study examines the inheritance of apospory in bahiagrass. A sexual plant was self-pollinated and crossed with an aposporous apomictic plant as pollen donor. Backcross and F2 progenies were obtained in several combinations. All self-pollinated sexual plants or sexual x sexual crosses produced progenies free of apospory. All crosses involving a sexual and an apomictic plant produced approximately three times more apospory-free plants than plants with apospory. Bahiagrass is of autotetraploid origin and hence is expected to display tetrasomic inheritance. The most widely accepted genetic model for inheritance of apospory in tropical grasses is a single dominant gene with tetrasomic inheritance. In the present experiments none of the apospory-free F1s segregated for the apospory trait indicating that it is most likely a dominant character. However, the observed results fit better a modified model: tetrasomic inheritance of a single dominant gene with pleiotropic effect and incomplete penetrance. The excess of apospory-free plants in the F1 progeny could be ascribed to some distortion in the segregation pattern due to a pleiotropic lethal effect of the dominant A allele with incomplete penetrance. Alternatively, partial lethality of factors linked to aposporous gene may account for segregation distortion against apospory.     

Single gene inheritance of occurrence of head spots in mice

Results from earlier selection studies indicated that while the size of head spots in mice descended from the Goodale head-spot strain was a quantitative, polygenic trait, head-spot occurrence was probably a qualitative trait inherited by one or two genes. The present study was undertaken to examine this possibility by crossing a head-spot stock with three inbred strains and with two noninbred stocks carrying mutant genes. Observed segregation ratios in the F2 and backcross generations of these crosses were compared to results expected under various models of qualitative inheritance. Evidence of linkage between known loci and a putative head-spot gene also was sought. Results indicated that head spotting was inherited primarily by the action of a recessive autosomal gene, head spot (hs). The action of this gene was subject to modification, in some crosses, by other genes or by environmental factors. Attempts to demonstrate linkage between the head spots and known single-locus traits were unsuccessful.     

Identification and linkage mapping of the phsA gene of Aspergillus nidulans, where mutation affects growth and pigmentation of colonies in a temperature- and pH-dependent way

We report the isolation and characterization of a mutant strain of the mold Aspergillus nidulans showing an altered response to environmental pH, including a reduction in its pH range for growth and the production of a melanin-like pigment at alkaline pH. We also show that the mutant strain is not detergent-sensitive and that its acid sensitivity is osmotically remediable with 0.5 M NaCl or 1.0 M sorbitol. Furthermore, the mutant phenotype is temperature-remediable with respect to pigmentation, extent of conidiation and growth diameter, with the restoration of a wild-type phenotype to the mutant strain being observed at 28 degrees C. On the other hand, the severity of the mutant phenotype is increased at 40 degrees C. Genetic analysis shows that this pH- and temperature-sensitive mutation, named phsA1, is located on the right arm of linkage group I of A. nidulans, between pabaA and yA, and that mutation phsA1 is recessive.     

Inheritance of glabrous plants in <Emphasis Type="Italic">Helianthemum oelandicum</Emphasis> var. <Emphasis Type="Italic">oelandicum</Emphasis> and spatial patterns of allele frequencies in local populations

Helianthemum oelandicum var. oelandicum is an endemic taxon on the Baltic island of Öland, SE Sweden. Plants can be classified into two morphs: the bristled morph (with bristles and with or without scattered stellate hairs) and the glabrous morph (without bristles and stellate hairs). In crosses between plants assumed to be homozygous for the trait that characterises the phenotypes of the two morphs, offspring in F1 could not be distinguished from the bristled morph. Segregation in F2 did not deviate from the expected 3:1 ratio (bristled morphs/glabrous morphs), indicating one major gene with a dominant allele for the phenotype of the bristled morph and a recessive allele for the phenotype of the glabrous morph. Besides the Mendelian inheritance of presence/absence of hairs, the density of hairs appeared to be further modified by quantitative genes. The frequency of the recessive allele for the phenotype of the glabrous morph varied among local populations and showed a geographical structure, both on local and regional scales. Possible mechanisms behind the spatial variation in indumentum are discussed.     

Investigation of inheritance of chronic inflammatory bowel diseases by complex segregation analysis.

OBJECTIVE--To investigate the mode of inheritance of ulcerative colitis and Crohn''s disease by complex segregation analysis. DESIGN--Cross sectional population based survey of familial occurrence of chronic inflammatory bowel disease. SETTING--Population of the Copenhagen county in 1987. SUBJECTS--662 patients in whom inflammatory bowel disease had been diagnosed before 1979, of whom 637 (96%) provided adequate information. Of 504 patients with ulcerative colitis, 54 had 77 relatives with ulcerative colitis and of 133 patients with Crohn''s disease, five had seven relatives with Crohn''s disease. MAIN OUTCOME MEASURES--Patterns of segregation of either disease as assessed by complex segregation analysis performed with the computer program POINTER. RESULTS--The analysis suggested that a major dominant gene with a penetrance of 0.20-0.26 is present in 9-13% of adult patients with ulcerative colitis. The analysis did not allow for other components in the familial aggregation. For Crohn''s disease the best fitting model included a major recessive gene with complete penetrance, for which 7% of the patients are homozygous. However, this model was not significantly different from a multifactorial model. CONCLUSIONS--The segregation pattern indicates that a major dominant gene has a role in ulcerative colitis, and suggests that a major recessive gene has a role in Crohn''s disease.