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Query: UNIPROT:Q86TM3 (
cage
)
29,987
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The experimental population genetics of Y-chromosome drive in Drosophila melanogaster is approximated by studying the behavior of T(Y;2),SD lines. These exhibit "pseudo-Y" drive through the effective coupling of the
Y chromosome
to the second chromosome meiotic drive locus, Segregation distorter (SD). T(Y;2),SD males consequently produce only male offspring. When such lines are allowed to compete against structurally normal SD(+) flies in population cages, T(Y;2),SD males increase in frequency according to the dynamics of a simple haploid selection model until the
cage
population is eliminated as a result of a deficiency in the number of adult females. Cage population extinction generally occurs within about seven generations.-Several conclusions can be drawn from these competition
cage
studies:(1) Fitness estimates for the T(Y;2),SD lines (relative to SD(+ )) are generally in the range of 2-4, and these values are corroborated by independent estimates derived from studies of migration-selection equilibrium. (2) Fitness estimates are unaffected by
cage
replication, sample time, or the starting frequency of T(Y;2),SD males, indicating that data from diverse cages can be legitimately pooled to give an overall fitness estimate. (3) Partitioning of the T(Y;2),SD fitnesses into components of viability, fertility, and frequency of alternate segregation (Y + SD from X + SD(+)) suggests that most of the T(Y;2),SD advantage derives from the latter two components. Improvements in the system might involve increasing both the viability and the alternate segregation to increase the total fitness. While pseudo-Y drive operates quite effectively against laboratory stocks, it is less successful in eliminating wild-type populations which are already segregating for suppressors of SD action. This observation suggests that further studies into the origin and rate of accumulation of suppressors of meiotic drive are needed before an overall assessment can be made of the potential of Y-chromosome drive as a tool for population control.
...
PMID:Experimental population genetics of meiotic drive systems. I. Pseudo-Y chromosomal drive as a means of eliminating cage populations of Drosophila melanogaster. 40 30
Anopheles albimanus males carrying an Y-autosome translocation were continuously released into a
cage
population at a ratio of 1:5 in favor of translocation males. The release caused a significant decrease in the absolute density of
cage
populations. Virtually complete replacement of wild type
Y chromosome
by translocated
Y chromosome
was observed after four generations. The results obtained from the
cage
experiments encourage actual field trials for the control of this vector species.
...
PMID:Studies on x-ray induced chromosomal translocations in Anopheles albimanus. III. Effect of the release of translocation males on the dynamics of cage populations. 125 80
Numerical chromosome aberrations are common in several types of malignant tumors. Recently, trisomy 7 and loss of the
Y chromosome
were described in cultures from nonneoplastic tissue, making the significance of these aberrations as
cancer-associated
changes doubtful. We herein report the mosaic occurrence of trisomy 7 in four consecutive short-term cultures initiated from normal kidney tissue. Smaller clones with trisomy 10 were present in three cases, and the only culture established from a male also showed mosaic loss of the
Y chromosome
.
...
PMID:Trisomy 7, trisomy 10, and loss of the Y chromosome in short-term cultures of normal kidney tissue. 236 38
Camptomelic syndrome is a severe malformation disorder affecting infant cartilage and bone formation. This syndrome is also characterized by sex reversal in a significant proportion of phenotypic females. In this case report, the authors describe a typical case of camptomelic syndrome in a black infant who had been exposed in utero to an oral contraceptive (OC). The infant was born after a full-term pregnancy. The mother had taken an OC containing 0.5-1.0 mg norethindrone and 0.035 mg ethinyl estradiol. Exposure had occurred for 6 months after conception. Parents were healthy and unrelated. The infant exhibited significant bone malformation in her legs, arms, feet, spine, and rib
cage
. Chromosome analysis yielded a normal 46,XY G-banded karyotype. The infant died at the age of 3 years, 6 months. Autopsy findings evidenced a female reproductive system. Microscopic examination of ovarian tissues revealed only immature sex cords; no oocytes were found. The authors briefly comment on camptomelic syndrome cases previously reported and implications of X-
Y chromosome
-gene effects associated with this syndrome. This may be the second reported case involving exposure to OCs early in pregnancy and sex reversal.
...
PMID:A genetic male infant with female phenotype in camptomelic syndrome: a possible relationship to exposure to oral contraceptives during pregnancy. 789 46
Aggressive and mating behaviors were assessed in XX females, XY females, and XY males of the C57BL/6/J/Ei ("C57BL/6" or "B6") strain of mouse. The
Y chromosome
of the XY females derives from Mus domesticus poschiavinus and the
Y chromosome
of the XY males derives from Mus musculus. The poschiavinus Y in the C57BL/6 background results in XY mice with either ovaries or ovotestes. Only those with ovaries were tested. These XY females appear to be endocrinologically identical to XX females. Aggressive and mating behaviors were also tested in XX males and XY males of the FVB/NtacfBR Odsex ("FVB") strain of mouse. The XX males have a transgene inserted 1 Mb upstream of the SOX9 gene, resulting in gonadal differentiation as a testis in the absence of a
Y chromosome
. C57BL/6 mice were tested for aggression in an instigated resident intruder paradigm and FVB/NtacfBR Odsex mice were tested for aggression in a neutral
cage
paradigm. Mice of both strains were tested with opponents of the same sex chromosome complement and gonadal sex. On the C57BL/6 background, the XY males were more aggressive than the XY and XX females, but there was no significant difference between the XX and XY females in aggression. On the FVB background, the XY and XX males were equally aggressive. Mice from both C57BL/6 and FVB backgrounds were tested for mating behaviors with females in hormonal estrus. On the C57BL/6 background, the XY males mounted more than the XY females, but there was no significant difference between the XY and XX females in mounting. On the FVB background, mounting, intromissions, and ejaculations were the same in XY and XX males. The implications of these findings for the effect of sex chromosome complement on sex differences in aggression and mating in mice are discussed.
...
PMID:Aggressive and mating behaviors in two types of sex reversed mice: XY females and XX males. 1806 53
In the house fly, Musca domestica L. (Diptera: Muscidae), sex is usually determined by a dominant factor, M, located on the
Y chromosome
. However, there are autosomal male (A(M)) populations in which the M factor is located on one or more of the five autosomes (I-V), most commonly on the third chromosome. Herein we report the use of isogenic strains to determine the relative fitness of Y(M) versus III(M) males in three different experiments. First, cages were started with 50% Y(M) and 50% III(M) males, and the frequencies of Y(M) and III(M) males were evaluated across generations. Second, mating competition studies were preformed with these isogenic strains. Third, the relative emergence rates of III(M) versus Y(M) male pupae held at three temperatures for 3 d were examined. All three studies indicate that III(M) males have a greater fitness than Y(M) males. In the
cage
competition studies, >90% of the males were III(M) after seven generations. III(M) males were more likely to mate than Y(M) males, and a higher percent of III(M) males emerged after being held as pupae at 4, 16, or 28 degrees C for 3 d. The implications of these studies to the distribution of III(M) and Y(M) males in field populations are discussed.
...
PMID:Selective advantage for IIIM males over YM males in cage competition, mating competition, and pupal emergence in Musca domestica L. (Diptera: Muscidae). 1938 1
Genetic breakdown occurred in a strain of Lucilia cuprina constructed for the purpose of genetic control of this pest. The strain incorporated autosomal recessive eye colour mutations linked in repulsion with a translocation involving the
Y chromosome
(male-determining) and two autosomes. In the original strain females had white eyes and males were wild type. The spontaneous breakdown involved a failure of the sex-limited inheritance of the eye colour mutations. Characteristically the frequency of white-eyed males increased rapidly in the strain, whereas the frequencies of the three other phenotypically recognizable breakdown products did not. This suggested that the white-eyed males had a selective advantage over both the wild type males and the other breakdown products. Genetic analysis revealed that recombination, which is normally rare in L. cuprina males, is considerably more frequent in the presence of a Y-autosome translocation, but that recombination alone was insufficient to account for the rate of increase of the white-eyed males in the colony. Genetic and cytological analysis of the breakdown products revealed that reversion of the multi-break translocation also occurred, and that many of the white-eyed males had either only a Y-single-autosome translocation or no translocation at all; thus these males were more fertile than the wild type multi-translocation males. In addition, under colony
cage
conditions the white-eyed males may have had a behavioural advantage in competition with the wild type males.
...
PMID:Genetic instability in mass-rearing colonies of a sex-linked translocation strain of Lucilia cuprina (Wiedemann) (Diptera: Calliphoridae) during a field trial of genetic control. 2430 49
