Genetic evidence that the sans fille locus is involved in Drosophila sex determination.

Abstract Females homozygous for sans fille1621 (= fs(1)1621) have an abnormal germ line. Instead of producing eggs, the germ-line cells proliferate forming ovarian tumors or excessive numbers of nurse cells. The Sex-lethal gene product(s) regulate the branch point of the dosage compensation and sex determination pathways in the soma. The role of Sex-lethal in the germ line is not clear but the germ line of females homozygous for female sterile Sex-lethal alleles or germ-line clones of loss-of-function alleles are characterized by ovarian tumors. Females heterozygous for sans fille1621 or Sex-lethal are phenotypically wild type with respect to viability and fertility but females trans-heterozygous for sans fille1621 and Sex-lethal show ovarian tumors, somatic sexual transformations, and greatly reduced viability.

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Analysis of the role of tra-1 in germline sex determination in the nematode Caenorhabditis elegans.

Genetics ◽

10.1093/genetics/123.4.755 ◽

1989 ◽

Vol 123 (4) ◽

pp. 755-769 ◽

Cited By ~ 3

Author(s):

T Schedl ◽

P L Graham ◽

M K Barton ◽

J Kimble

Keyword(s):

Caenorhabditis Elegans ◽

Sex Determination ◽

Germ Line ◽

Temperature Sensitive ◽

Loss Of Function ◽

Wild Type ◽

Allelic Series ◽

Isolation And Characterization ◽

Somatic Gonad

Abstract In wild-type Caenorhabditis elegans there are two sexes, self-fertilizing hermaphrodites (XX) and males (XO). To investigate the role of tra-1 in controlling sex determination in germline tissue, we have examined germline phenotypes of nine tra-1 loss-of-function (lf) mutations. Previous work has shown that tra-1 is needed for female somatic development as the nongonadal soma of tra-1(lf) XX mutants is masculinized. In contrast, the germline of tra-1(lf) XX and XO animals is often feminized; a brief period of spermatogenesis is followed by oogenesis, rather than the continuous spermatogenesis observed in wild-type males. In addition, abnormal gonadal (germ line and somatic gonad) phenotypes are observed which may reflect defects in development or function of somatic gonad regulatory cells. Analysis of germline feminization and abnormal gonadal phenotypes of the various mutations alone or in trans to a deficiency reveals that they cannot be ordered in an allelic series and they do not converge to a single phenotypic endpoint. These observations lead to the suggestion that tra-1 may produce multiple products and/or is autoregulated. One interpretation of the germline feminization is that tra-1(+) is necessary for continued specification of spermatogenesis in males. We also report the isolation and characterization of tra-1 gain-of-function (gf) mutations with novel phenotypes. These include temperature sensitive, recessive germline feminization, and partial somatic loss-of-function phenotypes.

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Differential effects of Sex-lethal mutations on dosage compensation early in Drosophila development.

Genetics ◽

10.1093/genetics/136.3.1051 ◽

1994 ◽

Vol 136 (3) ◽

pp. 1051-1061

Author(s):

M Bernstein ◽

T W Cline

Keyword(s):

Sex Determination ◽

X Chromosome ◽

Dosage Compensation ◽

Rna Splicing ◽

Lethal Gene ◽

Loss Of Function ◽

Developmental Pathway ◽

Pathway Choice ◽

Sex Lethal ◽

Blastoderm Stage

Abstract In response to the primary sex determination signal, X chromosome dose, the Sex-lethal gene controls all aspects of somatic sex determination and differentiation, including X chromosome dosage compensation. Two complementary classes of mutations have been identified that differentially affect Sxl somatic functions: (1) those impairing the "early" function used to set developmental pathway choice in response to the sex determination signal and (2) those impairing "late" functions involved in maintaining the pathway choice independent of the initiating signal and/or in directing differentiation. This "early vs. late" distinction correlates with a switch in promoter utilization from SxlPe to SxlPm at the blastoderm stage and a corresponding switch from transcriptional to RNA splicing control. Here we characterize five partial-loss-of-function Sxl alleles to explore a distinction between "early vs. late" functioning of Sxl in dosage compensation. Assaying for dosage compensation during the blastoderm stage, we find that the earliest phase of the dosage compensation process is controlled by products of the early Sxl promoter, SxlPe. Hence, in addition to triggering the sexual pathway decision of cells, products derived from SxlPe also control early dosage compensation, the first manifestation of sexually dimorphic differentiation. The effects of mutant Sxl alleles on early dosage compensation are consistent with their previous categorization as early vs. late defective with respect to their effects on pathway initiation. Results reported here suggest that the dosage compensation regulatory genes currently known to function downstream of Sxl, genes known as the "male-specific lethals," do not control all aspects of dosage compensation either at the blastoderm stage or later in development. In the course of this study, we also discovered that the canonical early defective allele, Sxlf9, which is impaired in its ability to establish the female developmental pathway commitment, is likely to be defective in the stability and/or functioning of products derived from SxlPe, rather than in the ability of SxlPe to respond to the chromosomal sex determination signal.

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The segmentation gene runt is needed to activate Sex-lethal, a gene that controls sex determination and dosage compensation in Drosophila

Genetics Research ◽

10.1017/s0016672300030470 ◽

1992 ◽

Vol 59 (3) ◽

pp. 189-198 ◽

Cited By ~ 26

Author(s):

Miguel Torres ◽

Lucas Sanchez

Keyword(s):

Sex Determination ◽

Dosage Compensation ◽

Relative Number ◽

Initial Step ◽

The Other ◽

Loss Of Function ◽

X Chromosomes ◽

Segmentation Gene ◽

Ectopic Activation ◽

Sex Lethal

SummaryIn Drosophila, sex is determined by the relative number of X chromosomes to autosomal sets (X: A ratio). The amount of products from several X-linked genes, called sisterless elements, is used to indicate to Sex-lethal the relative number of X chromosomes present in the cell. In response to the X: A signal, Sex-lethal is activated in females but remains inactive in males, being responsible for the control of both sex determination and dosage compensation. Here we find that the X-linked segmentation gene runt plays a role in this process. Reduced function of runt results in femalespecific lethality and sexual transformation of XX animals that are heterozygous for Sxl or sis loss-of-function mutations. These interactions are suppressed by SxlMI, a mutation that constitutively expresses female Sex-lethal functions, and occur at the time when the X: A signal determines Sex-lethal activity. Moreover, the presence of a loss-of-function runt mutation masculinizes triploid intersexes. On the other hand, runt duplications cause a reduction in male viability by ectopic activation of Sex-lethal. We conclude that runt is needed for the initial step of Sex-lethal activation, but does not have a major role as an X-counting element.

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fog-2, a germ-line-specific sex determination gene required for hermaphrodite spermatogenesis in Caenorhabditis elegans.

Genetics ◽

10.1093/genetics/119.1.43 ◽

1988 ◽

Vol 119 (1) ◽

pp. 43-61 ◽

Cited By ~ 3

Author(s):

T Schedl ◽

J Kimble

Keyword(s):

Caenorhabditis Elegans ◽

Sex Determination ◽

Germ Line ◽

Negative Regulator ◽

Loss Of Function ◽

Wild Type ◽

Negative Regulators ◽

Nematode Caenorhabditis Elegans ◽

Isolation And Characterization

Abstract This paper describes the isolation and characterization of 16 mutations in the germ-line sex determination gene fog-2 (fog for feminization of the germ line). In the nematode Caenorhabditis elegans there are normally two sexes, self-fertilizing hermaphrodites (XX) and males (XO). Wild-type XX animals are hermaphrodite in the germ line (spermatogenesis followed by oogenesis), and female in the soma. fog-2 loss-of-function mutations transform XX animals into females while XO animals are unaffected. Thus, wild-type fog-2 is necessary for spermatogenesis in hermaphrodites but not males. The fem genes and fog-1 are each essential for specification of spermatogenesis in both XX and XO animals. fog-2 acts as a positive regulator of the fem genes and fog-1. The tra-2 and tra-3 genes act as negative regulators of the fem genes and fog-1 to allow oogenesis. Two models are discussed for how fog-2 might positively regulate the fem genes and fog-1 to permit spermatogenesis; fog-2 may act as a negative regulator of tra-2 and tra-3, or fog-2 may act positively on the fem genes and fog-1 rendering them insensitive to the negative action of tra-2 and tra-3.

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The mog-1 gene is required for the switch from spermatogenesis to oogenesis in Caenorhabditis elegans.

Genetics ◽

10.1093/genetics/133.4.919 ◽

1993 ◽

Vol 133 (4) ◽

pp. 919-931 ◽

Cited By ~ 5

Author(s):

P L Graham ◽

J Kimble

Keyword(s):

Caenorhabditis Elegans ◽

Sex Determination ◽

Germ Cells ◽

Germ Line ◽

Loss Of Function ◽

Wild Type ◽

Per Se ◽

Post Transcriptional Regulation ◽

Germline Sex Determination ◽

Embryonic Death

Abstract Caenorhabditis elegans hermaphrodites make first sperm, then oocytes. By contrast, animals homozygous for any of six loss-of-function mutations in the gene mog-1 (for masculinization of the germ line) make sperm continuously and do not switch into oogenesis. Therefore, in mog-1 mutants, germ cells that normally would become oocytes are transformed into sperm. By contrast, somatic sexual fates are normal, suggesting that mog-1 plays a germ line-specific role in sex determination. Analyses of double mutants suggest that mog-1 negatively regulates the fem genes and/or fog-1: mog-1; fem and mog-1; fog-1 double mutants all make oocytes rather than sperm. Therefore, we propose that wild-type mog-1 is required in the hermaphrodite germ line for regulation of the switch from spermatogenesis to oogenesis rather than for specification of oogenesis per se. In addition to its role in germline sex determination, maternal mog-1 is required for embryogenesis: most progeny of a mog-1; fem or mog-1; fog-1 mother die as embryos. How might the roles of mog-1 in the sperm/oocyte switch and embryogenesis be linked? Previous work showed that fem-3 is regulated post-transcriptionally to achieve the sperm/oocyte switch. We speculate that mog-1 may function in the post-transcriptional regulation of numerous germ-line RNAs, including fem-3. A loss of mog-1 might inappropriately activate fem-3 and thereby abolish the sperm/oocyte switch; its loss might also lead to misregulation of maternal RNAs and thus embryonic death.

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Genetic evidence that the ovo locus is involved in Drosophila germ line sex determination.

Genetics ◽

10.1093/genetics/125.3.535 ◽

1990 ◽

Vol 125 (3) ◽

pp. 535-550 ◽

Cited By ~ 1

Author(s):

B Oliver ◽

D Pauli ◽

A P Mahowald

Keyword(s):

Drosophila Melanogaster ◽

Sex Determination ◽

Sexual Identity ◽

Gene Product ◽

Germ Cells ◽

Germ Line ◽

Partial Transformation ◽

Loss Of Function ◽

Lethal Allele ◽

Sex Lethal

Abstract Zygotically contributed ovo gene product is required for the survival of female germ cells in Drosophila melanogaster. Trans-allelic combinations of weak and dominant ovo mutations (ovoD) result in viable germ cells that appear to be partially transformed from female to male sexual identity. The ovoD2 mutation is partially suppressed by many Sex-lethal alleles that affect the soma, while those that affect only the germ line fail to interact with ovoD2. One of two loss-of-function ovo alleles is suppressed by a loss-of-function Sex-lethal allele. Because ovo mutations are germ line dependent, it is likely that ovo is suppressed by way of communication between the somatic and germ lines. A loss-of-function allele of ovo is epistatic to germ line dependent mutations in Sex-lethal. The germ line dependent sex determination mutation, sans fille, and ovoD mutations show a dominant synergistic interaction resulting in partial transformation of germ line sexual identity. The ovo locus appears to be involved in germ line sex determination and is linked in some manner to sex determination in the soma.

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Expression of the Sex-lethal gene is controlled at multiple levels during Drosophila oogenesis

Development ◽

10.1242/dev.118.3.797 ◽

1993 ◽

Vol 118 (3) ◽

pp. 797-812 ◽

Cited By ~ 19

Author(s):

D. Bopp ◽

J.I. Horabin ◽

R.A. Lersch ◽

T.W. Cline ◽

P. Schedl

Keyword(s):

Germ Cells ◽

Germ Line ◽

Basic Mechanism ◽

Lethal Gene ◽

Protein Distribution ◽

Wild Type ◽

Protein Levels ◽

Germ Cell Differentiation ◽

Cytoplasmic Accumulation ◽

Sex Lethal

In addition to controlling somatic sexual development in Drosophila melanogaster, the Sex-lethal (Sxl) gene is required for proper differentiation of female germ cells. To investigate its role in germ-line development, we have examined the expression of Sxl in wild-type ovaries and ovaries that are defective in early steps of germ cell differentiation. As in the soma, the basic mechanism for on/off regulation of Sxl relies on sex-specific processing of its transcripts in germ cells. One class of female-sterile mutations, which includes fs(1)1621 and the tumorous-ovary-producing allele of the ovarian tumor gene, otu1, is defective in the splicing process. These mutants have germ lines with high amounts of Sxl RNA spliced in the male mode and a severe reduction of protein levels in the germ cells. Another class of female-sterile mutations produces a phenotype similar to that seen in fs(1)1621 and otu1 but appears to express normal levels of Sxl protein in the germ cells. However, this second class does not show the changes in protein distribution normally observed in wild-type germ cells. In the wild-type germarium, the non-differentiated germ cells show a strong cytoplasmic accumulation of Sxl protein followed, as the germ cells differentiate, by a dramatic reduction and redistribution of the protein into nuclear foci. Interestingly, two female-sterile alleles of Sxl, Sxlf4 and Sxlf5 belong to the second class, which shows persistent cytoplasmic accumulation of Sxl protein. These Sxl female-sterile mutants encode an altered protein indicating that Sxl regulates processes that eventually lead to the changes in Sxl protein distribution. Lastly, we demonstrate that during the final stages of oogenesis several mechanisms must operate to prevent the progeny from inheriting Sxl protein. Conceivably, this regulation safeguards the inadvertent activation of the Sxl autoregulatory feedback loop in the male zygote.

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Sex determination in the germ line of Drosophila depends on genetic signals and inductive somatic factors

Development ◽

10.1242/dev.107.3.505 ◽

1989 ◽

Vol 107 (3) ◽

pp. 505-518 ◽

Cited By ~ 15

Author(s):

R. Nothiger ◽

M. Jonglez ◽

M. Leuthold ◽

P. Meier-Gerschwiler ◽

T. Weber

Keyword(s):

Sex Determination ◽

Germ Cells ◽

Germ Line ◽

The State ◽

Loss Of Function ◽

X Chromosomes ◽

Constitutive Mutation ◽

Sex Lethal ◽

Double Sex ◽

State Of Activity

We have analyzed the mechanism of sex determination in the germ line of Drosophila by manipulating three parameters: (1) the ratio of X-chromosomes to sets of autosomes (X:A); (2) the state of activity of the gene Sex-lethal (Sxl), and (3) the sex of the gonadal soma. To this end, animals with a ratio of 2X:2A and 2X:3A were sexually transformed into pseudomales by mutations at the sex-determining genes Sxl (Sex-lethal), tra (transformer), tra-2 (transformer-2), or dsx (double-sex). Animals with the karyotype 2X;3A were also transformed into pseudofemales by the constitutive mutation SxlM1. The sexual phenotype of the gonads and of the germ cells was assessed by phase-contrast microscopy. Confirming the conclusions of Steinmann-Zwicky et al. (Cell 57, 157, 1989), we found that all three parameters affect sex determination in germ cells. In contrast to the soma in which sex determination is completely cell-autonomous, sex determination in the germ line has a non-autonomous component inasmuch as the sex of the soma can influence the sexual pathway of the germ cells. Somatic induction has a clear effect on 2X;2A germ cells that carry a Sxl+ allele. These cells, which form eggs in an ovary, can enter spermatogenesis in testes. Mutations that cause partial loss of function or gain of function of Sxl thwart somatic induction and, independently of the sex of the soma, dictate spermatogenesis or oogenesis, respectively. Somatic induction has a much weaker effect on 2X;3A germ cells. This ratio is essentially a male signal for germ cells which consistently enter spermatogenesis in testes, even when they carry SxlM1. In a female soma, however, SxlM1 enables the 2X;3A germ cells to form almost normal eggs. Our results show that sex determination in the germ line is more complex than in the soma. They provide further evidence that the state of Sxl, the key gene for sex determination and dosage compensation in the soma, also determines the sex of the germ cells, and that, in the germ line, the state of activity of Sxl is regulated not only by the X:A ratio, but also by somatic inductive stimuli.

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Gain-of-Function Mutations of fem-3, a Sex-Determination Gene in Caenorhabditis elegans

Genetics ◽

10.1093/genetics/115.1.107 ◽

1987 ◽

Vol 115 (1) ◽

pp. 107-119 ◽

Cited By ~ 1

Author(s):

M Kathryn Barton ◽

Timothy B Schedl ◽

Judith Kimble

Keyword(s):

Sex Determination ◽

Germ Line ◽

Critical Role ◽

Temperature Shift ◽

Sensitive Period ◽

Temperature Sensitive ◽

Loss Of Function ◽

Wild Type ◽

Gain Of Function ◽

In The Wild

ABSTRACT We have isolated nine gain-of-function (gf) alleles of the sex-determination gene fem-3 as suppressors of feminizing mutations in fem-1 and fem-2. The wild-type fem-3 gene is needed for spermatogenesis in XX self-fertilizing hermaphrodites and for male development in both soma and germ line of XO animals. Loss-of-function alleles of fem-3 transform XX and XO animals into females (spermless hermaphrodites). In contrast, fem-3(gf) alleles masculinize only one tissue, the hermaphrodite germ line. Thus, XX fem-3(gf) mutant animals have a normal hermaphrodite soma, but the germ line produces a vast excess of sperm and no oocytes. All nine fem-3(gf) alleles are temperature sensitive. The temperature-sensitive period is from late L4 to early adult, a period just preceding the first signs of oogenesis. The finding of gain-of-function alleles which confer a phenotype opposite to that of loss-of-function alleles supports the idea that fem-3 plays a critical role in germ-line sex determination. Furthermore, the germ-line specificity of the fem-3(gf) mutant phenotype and the late temperature-sensitive period suggest that, in the wild-type XX hermaphrodite, fem-3 is negatively regulated so that the hermaphrodite stops making sperm and starts making oocytes. Temperature shift experiments also show that, in the germ line, sexual commitment appears to be a continuing process. Spermatogenesis can resume even after oogenesis has begun, and oogenesis can be initiated much later than normal

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Microtubule–microtubule sliding by kinesin-1 is essential for normal cytoplasmic streaming in Drosophila oocytes

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1522424113 ◽

2016 ◽

Vol 113 (34) ◽

pp. E4995-E5004 ◽

Cited By ~ 41

Author(s):

Wen Lu ◽

Michael Winding ◽

Margot Lakonishok ◽

Jill Wildonger ◽

Vladimir I. Gelfand

Keyword(s):

Cytoplasmic Streaming ◽

Cell Types ◽

Nurse Cells ◽

Wild Type ◽

Actin Cortex ◽

Microtubule Motor ◽

Multiple Cell ◽

Cytoplasmic Microtubules ◽

Two Populations

Cytoplasmic streaming in Drosophila oocytes is a microtubule-based bulk cytoplasmic movement. Streaming efficiently circulates and localizes mRNAs and proteins deposited by the nurse cells across the oocyte. This movement is driven by kinesin-1, a major microtubule motor. Recently, we have shown that kinesin-1 heavy chain (KHC) can transport one microtubule on another microtubule, thus driving microtubule–microtubule sliding in multiple cell types. To study the role of microtubule sliding in oocyte cytoplasmic streaming, we used a Khc mutant that is deficient in microtubule sliding but able to transport a majority of cargoes. We demonstrated that streaming is reduced by genomic replacement of wild-type Khc with this sliding-deficient mutant. Streaming can be fully rescued by wild-type KHC and partially rescued by a chimeric motor that cannot move organelles but is active in microtubule sliding. Consistent with these data, we identified two populations of microtubules in fast-streaming oocytes: a network of stable microtubules anchored to the actin cortex and free cytoplasmic microtubules that moved in the ooplasm. We further demonstrated that the reduced streaming in sliding-deficient oocytes resulted in posterior determination defects. Together, we propose that kinesin-1 slides free cytoplasmic microtubules against cortically immobilized microtubules, generating forces that contribute to cytoplasmic streaming and are essential for the refinement of posterior determinants.

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