Two major regulatory genes for mammalian sex determination and differentiation

Genetica ◽  
1984 ◽  
Vol 52-53 (1) ◽  
pp. 267-273
Author(s):  
Susumu Ohno
Keyword(s):  
Sex Determination ◽  
Regulatory Genes

Major sex-determining genes and the control of sexual dimorphism in Caenorhabditis elegans

Genome ◽  
1989 ◽  
Vol 31 (2) ◽  
pp. 625-637 ◽  
Author(s):  
Jonathan Hodgkin ◽  
Andrew D. Chisholm ◽  
Michael M. Shen
Keyword(s):  
Caenorhabditis Elegans ◽  
Sex Determination ◽  
X Chromosome ◽  
Germ Line ◽  
Cell Lineage ◽  
Regulatory Genes ◽  
Nematode Caenorhabditis Elegans ◽  
X Chromosomes ◽  
The Many ◽  
Lineage Analysis

Sex determination in Caenorhabditis elegans involves a cascade of major regulatory genes connecting the primary sex determining signal, X chromosome dosage, to key switch genes, which in turn direct development along either male or female pathways. Animals with one X chromosome (XO) are male, while animals with two X chromosomes (XX) are hermaphrodite: hermaphrodite development occurs because the action of the regulatory genes is modified in the germ line so that both sperm and oocytes are made inside a completely female soma. The regulatory genes are being examined by both genetic and molecular means. We discuss how these major genes, in particular the last switch gene in the cascade, tra-1, might regulate the many different sex-specific events that occur during the development of the hermaphrodite and of the male.Key words: nematode, Caenorhabditis elegans, sex determination, sexual differentiation, cell lineage analysis.

scholarly journals Introduction

Development ◽  
1987 ◽  
Vol 101 (Supplement) ◽  
pp. 1-1 ◽  
Author(s):  
Peter N. Goodfellow
Keyword(s):  
Sex Determination ◽  
Molecular Cloning ◽  
Genetic Control ◽  
Regulatory Genes ◽  
Control Gene ◽  
Developmental Control ◽  
Phenotypic Changes ◽  
Pleiotrophic Effects ◽  
Master Control ◽  
Testis Determining Gene

The current dogma describing the genetic control of development assumes a hierarchy of regulatory genes. In the simplest case, a master control gene directly regulates secondary genes which, in turn, regulate the expression of other genes. In principle the master control genes can be recognized by the pleiotrophic effects caused by mutation, however, complex phenotypic changes are also associated with mutations in many nonregulatory genes. The bestdescribed examples of control genes are from relatively simple organisms with well-developed genetics, for example Drosophila and Caenorhabdltis. Unfortunately, identification of developmental control genes in mammals has proved to be difficult, presumably because homeotic and similar mutations are lethal. There is, however, one well-defined developmental control gene in mammals: TDF or the testis-determining gene (the same locus is called Tdy in mouse). Molecular cloning of TDF will not only facilitate exploration of the fundamental questions of sex determination, but should also provide a model for genetic control of development.

scholarly journals ACTIVITY OF THE SEX-DETERMINING GENE tra-2 IS MODULATED TO ALLOW SPERMATOGENESIS IN THE C. ELEGANS HERMAPHRODITE

Genetics ◽  
1986 ◽  
Vol 114 (1) ◽  
pp. 53-76
Author(s):  
Tabitha Doniach
Keyword(s):  
Sex Determination ◽  
Regulatory Genes ◽  
The State ◽  
The Self ◽  
Wild Type ◽  
Gain Of Function ◽  
C Elegans ◽  
Male Development ◽  
In The Wild ◽  
Mode Of Regulation

ABSTRACT In the nematode C. elegans, there are two sexes, the self-fertilizing hermaphrodite (XX) and the male (XO). The hermaphrodite is essentially a female that makes sperm for a brief period before oogenesis. Sex determination in C. elegans is controlled by a pathway of autosomal regulatory genes, the state of which is determined by the X:A ratio. One of these genes, tra-2, is required for hermaphrodite development, but not for male development, because null mutations in tra-2 masculinize XX animals but have no effect on XO males. Dominant, gain-of-function tra-2 mutations have now been isolated that completely feminize the germline of XX animals so that they make only oocytes and no sperm and, thus, are female. Most of the tra-2(dom) mutations do not correspondingly feminize XO animals, so they do not appear to interfere with control by her-1, a gene thought to negatively regulate tra-2 in XO animals. Thus, these mutations appear to cause gain of tra-2 function in the XX animal only. Dosage studies indicate that 5 of 7 tra-2(dom) alleles are hypomorphic, so they do not simply elevate XX tra-2 activity overall. These properties suggest that in the wild type, tra-2 activity is under two types of control: (1) in males, it is inactivated by her-1 to allow male development to occur, and (2) in hermaphrodites, tra-2 is active but transiently inactivated by another, unknown, regulator to allow hermaphrodite spermatogenesis; this mode of regulation is hindered by the tra-2(dom) mutations, thereby resulting in XX females.

Molecular genetic aspects of sex determination in Drosophila melanogaster

Genome ◽  
1989 ◽  
Vol 31 (2) ◽  
pp. 638-645 ◽  
Author(s):  
B. S. Baker ◽  
K. Burtis ◽  
T. Goralski ◽  
W. Mattox ◽  
R. Nagoshi
Keyword(s):  
Drosophila Melanogaster ◽  
Sex Determination ◽  
Sexual Differentiation ◽  
Rna Processing ◽  
Molecular Basis ◽  
Rna Binding ◽  
Regulatory Genes ◽  
Regulatory State ◽  
Splice Acceptor ◽  
Regulatory Cascade

The molecular analyses of three of the regulatory genes (transformer (tra), doublesex (dsx), and transformer-2 (tra-2)) controlling sexual differentiation in Drosophila have demonstrated that the control of RNA processing has a major role in regulating somatic sexual differentiation. The activities of both the tra and dsx genes are controlled at the level of RNA processing. In the case of tra the use of different splice acceptor sites results in a functional transcript being produced only in females, whereas at dsx the use of different splice acceptor sites in the two sexes results in the production of transcripts that encode different proteins in males and females. The tra-2 gene has been shown to be necessary for the processing of the dsx pre-mRNA in females and the conceptual translation of a tra-2 cDNA shows that it encodes a protein with similarity to a family of RNA-binding proteins which includes known splicesome components. We previously suggested that the pattern of sexual differentiation and dosage compensation characteristic of a male was a default regulatory state. The findings reviewed here provide a molecular basis for this default expression in males as well as an insight into how females differ from males in control of the expression of these genes. For both the tra and dsx genes the molecular basis of their male (default) state of expression appears to be the processing of their transcripts by the housekeeping RNA splicing machinery. In females the specification of the alternative pattern of splicing at both tra and dsx is by the sex determination regulatory genes that function upstream of them in this regulatory cascade. It seems likely that the activities of these sex determination regulatory genes in females do not provide all of the information that is necessary for proper splicing of the transcripts of the genes downstream of them. Rather we imagine that the products of the Sxl, tra, and tra-2 genes are acting to impose a specificity on the basic cellular splicing machinery.Key words: Drosophila melanogaster, sex determination, sexual differentiation.

scholarly journals A genetic analysis of hermaphrodite, a pleiotropic sex determination gene in Drosophila melanogaster.

Genetics ◽  
1994 ◽  
Vol 136 (1) ◽  
pp. 195-207
Author(s):  
M A Pultz ◽  
G S Carson ◽  
B S Baker
Keyword(s):  
Drosophila Melanogaster ◽  
Genetic Analysis ◽  
Sex Determination ◽  
Temperature Sensitivity ◽  
Sexual Differentiation ◽  
Regulatory Genes ◽  
Temperature Sensitive ◽  
Partial Loss ◽  
Female Progeny ◽  
Regulatory Cascade

Abstract Sex determination in Drosophila is controlled by a cascade of regulatory genes. Here we describe hermaphrodite (her), a new component of this regulatory cascade with pleiotropic zygotic and maternal functions. Zygotically, her+ function is required for female sexual differentiation: when zygotic her+ function is lacking, females are transformed to intersexes. Zygotic her+ function may also play a role in male sexual differentiation. Maternally, her+ function is needed to ensure the viability of female progeny: a partial loss of her+ function preferentially kills daughters. In addition, her has both zygotic and maternal functions required for viability in both sexes. Temperature sensitivity prevails for all known her alleles and for all of the her phenotypes described above, suggesting that her may participate in an intrinsically temperature-sensitive process. This analysis of four her alleles also indicates that the zygotic and maternal components of of her function are differentially mutable. We have localized her cytologically to 36A3-36A11.

Sex determination banned in India

Nature ◽  
1996 ◽  
Vol 379 (6562) ◽  
pp. 201-201
Keyword(s):  
Sex Determination

Sex determination and Y chromosome constitutive heterochromatin

2019 ◽  
Vol 1 (1) ◽  
pp. 1-5
Author(s):  
Abyt Ibraimov
Keyword(s):  
Sex Determination ◽  
Y Chromosome ◽  
Constitutive Heterochromatin ◽  
Sex Differentiation ◽  
Secondary Sexual Characteristics ◽  
Biological Meaning ◽  
Heterochromatin Block ◽  
Sexual Characteristics ◽  
Open Question ◽  
Efficient Elimination

In many animals, including us, the genetic sex is determined at fertilization by sex chromosomes. Seemingly, the sex determination (SD) in human and animals is determined by the amount of constitutive heterochromatin on Y chromosome via cell thermoregulation. It is assumed the medulla and cortex tissue cells in the undifferentiated embryonic gonads (UEG) differ in vulnerability to the increase of the intracellular temperature. If the amount of the Y chromosome constitutive heterochromatin is enough for efficient elimination of heat difference between the nucleus and cytoplasm in rapidly growing UEG cells the medulla tissue survives. Otherwise it doomed to degeneration and a cortex tissue will remain in the UEG. Regardless of whether our assumption is true or not, it remains an open question why on Y chromosome there is a large constitutive heterochromatin block? What is its biological meaning? Does it relate to sex determination, sex differentiation and development of secondary sexual characteristics? If so, what is its mechanism: chemical or physical? There is no scientifically sound answer to these questions.

SEX DETERMINATION OF FETUS PRENATAL FROM MATERNAL PLASMA BY USING DUPLEX PCR TECHNIQUE IN GOAT

2014 ◽  
Vol 13 (1) ◽  
pp. 50-59
Author(s):  
A NisreenYasirJasim ◽  
Tahir A. Fahid ◽  
Talib Ahmed Jaayid
Keyword(s):  
Sex Determination ◽  
Maternal Plasma ◽  
Duplex Pcr

Dynamics of fatty acid regulatory genes during ovarian development in Penaeus monodon

Reproduction ◽  
2018 ◽  
Author(s):  
Pacharawan Deenarn ◽  
Punsa Tobwor ◽  
Rungnapa Leelatanawit ◽  
Somjai Wongtriphop ◽  
Jutatip Khudet ◽  
...  
Keyword(s):  
Fatty Acid ◽  
Ovarian Development ◽  
Penaeus Monodon ◽  
Chain Fatty Acid ◽  
Regulatory Genes ◽  
Ovarian Maturation ◽  
Long Chain Fatty Acid ◽  
Eyestalk Ablation ◽  
Regulatory Pathways ◽  
Expression Levels

The delay in ovarian maturation in farmed black tiger shrimp Penaeus monodon has resulted in the widespread practice of feeding broodstock with the polychaetes Perinereis nuntia and their unilateral eyestalk ablation. Although this practice alters fatty acid content in shrimp ovaries and hepatopancreas, its effects on fatty acid regulatory genes have yet to be systematically examined. Here, microarray analysis was performed on hepatopancreas and ovary cDNA collected from P. monodon at different ovarian maturation stages, revealing that 72 and 58 genes in fatty acid regulatory pathways were differentially expressed in hepatopancreas and ovaries respectively. Quantitative real-time PCR analysis revealed that ovarian maturation was associated with higher expression levels of acetyl-CoA acetyltransferase, acyl-CoA dehydrogenase, acyl-CoA oxidase 3 and long-chain fatty acid transport protein 4 in hepatopancreas, whereas the expression levels of 15 fatty acid regulatory genes were increased in shrimp ovaries. To distinguish the effects of different treatments, transcriptional changes were examined in P. monodon with stage 1 ovaries before polychaete feeding, after one-month of polychaete feeding and after eyestalk ablation. Polychaete feeding resulted in lower expression levels of enoyl-CoA hydratase and acyl-CoA synthetase medium-chain family member 4, while the expression level of phosphatidylinositide phosphatase SAC1 was higher in shrimp hepatopancreas and ovaries. Additionally, eyestalk ablation resulted in a higher expression level of long-chain fatty acid-CoA ligase 4 in both tissues. Together, our findings describe the dynamics of fatty acid regulatory pathways during crustacean ovarian development and provide potential target genes for alternatives to eyestalk ablation in the future.

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