ANOTHER LOOK AT THE SINGLE-ACTIVE-X HYPOTHESIS

Embryonic loss of human females with partial trisomy 19 identifies region critical for the single active X

To compensate for the sex difference in the number of X chromosomes, human females, like human males have only one active X. The other X chromosomes in cells of both sexes are silenced in utero by XIST, the Inactive X Specific Transcript gene, that is present on all X chromosomes. To investigate the means by which the human active X is protected from silencing by XIST, we updated the search for a key dosage sensitive XIST repressor using new cytogenetic data with more precise resolution. Here, based on a previously unknown sex bias in copy number variations, we identify a unique region in our genome, and propose candidate genes that lie within, as they could inactivate XIST. Unlike males, the females who duplicate this region of chromosome 19 (partial 19 trisomy) do not survive embryogenesis; this preimplantation loss of females may be one reason that more human males are born than females.

Random X-chromosome inactivation dynamics in vivo by single-cell RNA sequencing

Background

Random X-chromosome inactivation (rXCI) is important for the maintenance of normal somatic cell functions in female eutherian mammals. The dynamics of X-chromosome inactivation initiation has been widely studied by assessing embryonic stem cell differentiation in vitro. To investigate the phenomenon in vivo, we applied RNA sequencing to single cells from female embryos obtained from a natural intercrossing of two genetically distant mouse strains. Instead of artificially assigning the parental origin of the inactive X chromosome, the inactive X chromosomes in this study were randomly selected from the natural developmental periods and thus included both paternal and maternal origins.

Results

The rXCI stages of single cells from the same developmental stage showed heterogeneity. The high resolution of the rXCI dynamics was exhibited. The inactivation orders of X chromosomal genes were determined by their functions, expression levels, and locations; generally, the inactivation order did not exhibit a parental origin preference. New escape genes were identified. Ohno’s hypothesis of dosage compensation was refuted by our post-implantation stage data.

Conclusions

We found the inactivation orders of X chromosomal genes were determined by their own properties. Generally, the inactivation order did not exhibit a parental origin preference. It provided insights into the gene silencing dynamics during rXCI in vivo.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-016-3466-8) contains supplementary material, which is available to authorized users.

X-chromosome inactivation and escape

X-chromosome inactivation, which was discovered by Mary Lyon in 1961 results in random silencing of one X chromosome in female mammals. This review is dedicated to Mary Lyon, who passed away last year. She predicted many of the features of X inactivation, for e.g., the existence of an X inactivation center, the role of L1 elements in spreading of silencing and the existence of genes that escape X inactivation. Starting from her published work here we summarize advances in the field.

Regulation of X-chromosome inactivation by the X-inactivation centre

X-chromosome inactivation (XCI) ensures dosage compensation in mammals and is a paradigm for allele-specific gene expression on a chromosome-wide scale. Important insights have been made into the developmental dynamics of this process. Recent studies have identified several cis- and trans-acting factors that regulate the initiation of XCI via the X-inactivation centre. Such studies have shed light on the relationship between XCI and pluripotency. They have also revealed the existence of dosage-dependent activators that trigger XCI when more than one X chromosome is present, as well as possible mechanisms underlying the monoallelic regulation of this process. The recent discovery of the plasticity of the inactive state during early development, or during cloning, and induced pluripotency have also contributed to the X chromosome becoming a gold standard in reprogramming studies.

Red-Light Thresholds in Heterozygote Carriers of Protanopia: Genetic Implications

Absolute thresholds in response to red light were compared in nine normal subjects, six female carriers of protanopia (heterozygotes), and six male subjects with protanopia. The fovea and four peripheral retinal areas were tested, and all data were obtained before the occurrence of the rod-cone break. Elevated thresholds were found in all retinal areas tested in protanopic males, at the fovea in all carriers, and in some peripheral retinal areas in two carriers. The thresholds for carriers were far below those for the protanopic males, and no greater variability of threshold was found in the carriers when they were compared with the normal control group. The findings do not substantiate the occurrence of inactivation at the locus on the X chromosome for protanopia.

Identification and characterization of the human XIST gene promoter: implications for models of X chromosome inactivation

The XIST gene in both humans and mice is expressed exclusively from the inactive X chromosome and is required for X chromosome inactivation to occur early in development. In order to understand transcriptional regulation of the XIST gene, we have identified and characterized the human XIST promoter and two repeated DNA elements that modulate promoter activity. As determined by reporter gene constructs, the XIST minimal promoter is constitutively active at high levels in human male and female cell lines and in transgenic mice. We demonstrate that this promoter activity is dependent in vitro upon binding of the common transcription factors SP1, YY1 and TBP. We further identify two cis -acting repeated DNA sequences that influence reporter gene activity. First, DNA fragments containing a set of highly conserved repeats located within the 5'-end of XIST stimulate reporter activity 3-fold in transiently transfected cell lines. Second, a 450 bp alternating purine-pyrimidine repeat located 25 kb upstream of the XIST promoter partially suppresses promoter activity by approximately 70% in transient transfection assays. These results indicate that the XIST promoter is constitutively active and that critical steps in the X inactivation process must involve silencing of XIST on the active X chromosome by factors that interact with and/or recognize sequences located outside the minimal promoter.

X chromosome retains the memory of its parental origin in murine embryonic stem cells

A cytogenetic and biochemical study of balloon-like cystic embryoid bodies, formed by newly established embryonic stem (ES) cell lines having a cytogenetically or genetically marked X chromosome, revealed that the paternally derived X chromosome was inactivated in the majority of cells in the yolk sac-like mural region consisting of the visceral endoderm and mesoderm. The nonrandomness was less evident in the more solid polar region containing the ectodermal vesicle, mesoderm and visceral endoderm. Since the same was true in embryoid bodies derived from ES cells at the 30th subculture generation, it was concluded that the imprinting responsible for the preferential inactivation of the paternal X chromosome that was limited to non-epiblast cells of the female mouse embryos, was stably maintained in undifferentiated ES cells. Differentiating epiblast cells should be able to erase or avoid responding to the imprint.

Karyotypes and X chromosome inactivation in segregants of a murine X-autosome translocation, T(X;4)37H

Karyotypes and X chromosome inactivation were studied in embryos obtained from female mice carrying T(X;4)37H translocation on day 6 to 8 of gestation by a BrdU-acridine orange method. A total of 18 different karyotypes were found in 477 embryos examined: 90.0% embryos were products expected from 2:2 alternate or adjacent 1 disjunction. 3:1 and adjacent 2 disjunctions accounted for approximately 8.0% and 0.7% conceptuses, respectively. In the embryo proper of balanced T37H/ + conceptuses, inactivation was random with respect to the normal X and the larger translocation X (4x) chromosome. In all the cells with the 4x inactive, the late replication apparently did not spread to the attached autosomal portion, although black/brown coat variegation implies spreading of inactivation into the autosomal region. The X chromosome segment deprived of the inactivation center remained active in all the cells examined and it exerted deleterious effects on embryonic or fetal development. Observation in embryos having two maternally derived X chromosomes showed that they were indeed resistant to inactivation in early extraembryonic cell lineages, and two copies of active X chromosomes in the trophectoderm fatally affected embryonic development due to inability to form the extraembryonic ectoderm and ectoplacental cone from the polar trophectoderm. In unbalanced X aneuploids the X chromosomes with the deletion were preferentially inactivated due to strong selection against nullisomy X.

X-ray-induced specific locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. I. Modification of the heterozygous effects of multilocus deletions covering the ad-3A or ad-3B loci

The basis for the reduced growth rates of heterokaryons between strains carrying nonallelic combinations of gene/point mutations (ad-3R) and multilocus deletion mutations (ad-3IR) has been investigated by a simple genetic test. The growth rates of forced 2-component heterokaryons (dikaryons) between multilocus deletion mutations were compared with forced 3-component heterokaryons (trikaryons) containing an ad-3AR ad-3BR double mutant as their third component. Since the third component has no genetic damage at other loci immediately adjacent to the ad-3A or ad-3B locus, the growth rate on minimal medium depends on the functional activity of the unaltered (and presumed "wild-type") ad-3A and ad-3B loci in the first two components. In many cases, the requirements of the original dikaryons have been satisfied by the addition of unaltered genes (in the third component), and these trikaryons grow at wild-type rate on minimal medium. Those trikaryons growing at less than wild-type rate were shown to be adenine-requiring, and wild-type growth rate was obtained with the addition of low levels of adenine to the medium. Such tests in the present experiments have shown that ad-3IR mutations result not only in inactivation of the ad-3 loci by multilocus deletion but also, in many cases, in partial gene inactivation by an unknown mechanisms at other loci in the immediately adjacent regions. The heterozygous effects observed in our present experiments with multilocus deletions in Neurospora can be explained either by a spreading-type position effect of the type found by others in Drosophila, mice, Oenothera and Aspergillus or by undetected genetic damage ("cryptic mutations") in the immediately adjacent genetic regions. An attempt will be made to distinguish between these two alternative hypotheses with techniques for DNA cloning and sequencing in future experiments.

Insect sex chromosomes. VI. A presumptive hyperactivation of the male X chromosome in Acheta domesticus (L.)

The functional status of the X chromosome in Acheta domesticus has been analysed at the whole chromosome level on the basis of (1) 3H-thymidine autoradiography, (2) 5-BrdU/AO fluorescence microscopy (3) in vivo 5-BrdU incorporation and (4) 3H-UdR induced aberrations. The rationale of these techniques in relation to the functional aspect of the X chromosome is that the inactive X chromosome would (1) show asynchrony in DNA synthesis, (2) show differential fluorescence, (3) respond differentially to in vivo 5-BrdU treatment and (4) the active X chromosome would show aberrations when treated with 3H-Uridine. From the results, it appears that the X chromosomes in both male (XO) and female (XX) somatic cells of Acheta are euchromatic (active). Further, the single X in the male is transcriptionally as active as the two X chromosomes in the female. In other words, the single X in the male is hyperactive when compared with the single X in the female. From this it is inferred that the male X chromosome is differentially regulated in order to bring about an equalization of it's gene product(s) to that produced by both Xs in the female. Drosophila melanogaster has a comparable system of dosage compensation. Thus, Acheta is yet another insect showing evidence for an X chromosome regulatory mechanism of dosage compensation. Additionally, it is surmised that sex determination in Acheta is based on an autosomes/X chromosome balance mechanism.

Controlling elements in the mouse. IV. Evidence of non-random X-inactivation

The non-randomXchromosome expression that has been observed with coat markers in female mice heterozygous for theXcealleles,XceaandXceb, has now been investigated with the electrophoretic enzyme marker,Pgk-1. Because theXcestatus of thePgk-1amarked chromosome was not known, PGK expression was assessed inPgk-1a/Pgk-lbheterozygotes which carried eitherXceaorXcebon theirPgk-1bchromosome. The PGK-1A allozyme was found to predominate in both genotypes but whenXcebwas present on thePgk-lbchromosome the expression of the two allo-zymes was less unequal. This effect was seen in both liver and kidney of adults and to at least the same degree in embryos aged 13·5 and 7·5 days. The results have been interpreted to mean that the non-randomXexpression derives from a primary non-randomness of theXinactivation process and that a new and more extremeXceallele, designatedXcec, was present on thePgr-1a-markedXchromosome.

Primary and secondary nonrandom X chromosome inactivation in early female mouse embryos carrying Searle's translocation T(X; 16)16H

By means of a cytological technique involving 5-bromodeoxyuridine, acridine orange, and fluorescence microscopy, the asynchronously replicating, hence genetically inactivated, X chromosome was identified in 6- to 8-day embryos from female mice heterozygous for Searle's translocation T(X;16)16H (abbreviated as T16H) mated with either karyotypically normal males or males carrying Cattanach's translocation T(X;7)1Ct in order to analyse the way in which the total inactivation of the normal X is achieved in adult T16H heterozygotes. Embryos examined included 9 Xn/X(7);16/16, 3 X 16/Xn;16x/16, 12 X16/X(7); 16x/16, 5 X16/Xn;16/16, 8 X16/X(7); 16/16 and 2 Xn/Y; 16x/16/16. In these notations X16, 16x, X(7) and Xn represent Searle's X with the centromeric segment of the X, Searle's X with the centomeric segment of chromosome 16, Cattanach's X with insertion of a chromosome 7 segment, and normal X, respectively. The X(7) exerted no apparent effect upon embryonic development up to the 8th day of gestation and X chromosome inactivation. -- The asynchronously replicating X was the Xn in X16/Xn;16x/16 and X(7) in X16/X(7);16x/16 embryos except a small number of cells on day 6 (13/493) and on day 7 (1/886) in which almost the entire 16x replicated asynchronously. The X16, on the other hand, never showed replication asynchrony. That the X16 is indeed unable to become inactivated was indicated by the observation that the X16 as well as Xn or X(7) did not replicate asynchronously in Xn/X16;16/16 and X16/X(7);16/16 embryos X16-inactive cell lines, if occurring, should have been genetically less unbalanced than any other cell line in such embryos. It is highly likely therefore that the ultimate inactivation pattern in T16H heterozygotes has been accomplished by (1) the inability of the X16 to become inactive; (2) inactivation in favor of the Xn; and (3) rapid elimination of 16x-inactive cells. Severe growth retardatin and early death of X16/Xn;16/16 and X16/X(7);16/16 embryos having no inactive X suggested that functional X disomy is detrimental to embryogenesis. These embryos further indicated that the concurrence of at least two X chromosomal loci separated by the T16H breakpoint is necessary for the homologous X chromosome becoming inactivated.

Stochastic models for X chromosome inactivation

A multivariate Gaussian model for mammalian development is presented with the associated biological and mathematical assumptions. Many biological investigations use the female mammal X chromosome to test hypotheses and to estimate parameters of the developmental system. In particular, Lyon's (1961) hypotheses are used as a basis of the mathematical model. Experimental mouse data and three sets of human experimental data are analyzed using the hypothesized Gaussian model. The estimated biological parameters are consistent with some current biological theories.

Variation for X chromosome expression in mice detected by electrophoresis of phosphoglycerate kinase

The proportions of the two isozyme bands of the X-linked form of phosphoglycerate kinase (PGK-1) were compared in 16 tissues from four groups of adult heterozygous females. Little evidence was found for differences in expression of the two isozymes among tissues but there was a marked difference among the four groups of mice. The proportion of the PGK-1B enzyme was consistently lower in PGK-1AB heterozygous daughters of C3H/HeHa females than in corresponding heterozygotes with a C57BL/6Ha, DBA/2Ha or JBT/Jd mother. This difference was also observed in foetuses on the fourteenth day of gestation irrespective of whether the C3H/HeHaXchromosome was derived from the mother or the father. Sequential sampling of blood from the same heterozygous females provided no evidence for genetically determined cell selection in the adult erythropoietic tissue. The observed differences probably reflect variation at anX-chromosome controlling element locus among inbred strains of mice, similar to that described by Cattanach & Williams (1972) usingX-linked morphological markers, although this has yet to be tested.

Assessment of the value of factor VIII procoagulant and antigen ratio in the diagnosis of carriers of haemophilia

The detection rate of carriers of haemophilia was evaluated using the ratio of factor VIII procoagulant activity (VIIIc) to factor VIII antigen (VIIIag). In normals the corelation coefficient of VIIIc to VIIIag was 0.82. In 15 obligatory carriers of haemophilia whose VIIIc and VIIIag levels were studied in the authors' labotatory there was no correlation between VIIIc and VIIIag and the ratio of VIIIc to VIIIag was below the lowest normal value in 12 (80%). In all five obligatory carriers whose VIIIc levels were estimated in the referring institution and VIIIag levels in the authors' laborary the ratio was below the lowest normal value. In 17 sisters of haemophiliacs studied here or referred for estimation of VIIIag only, an abnormal ratio was found in seven. Of 25 mothers of haemophilic children without a family history of haemophilia carriers is close to that expected on theoretical grounds but the interpretation of the results is complicated by the small numbers of patients all of whose studies were performed entirely in the authors' laboratory. In two normal individuals, one of who was on a contraceptive pill, there were no fluctuations of the ratio of VIIIc to VIIIag during the menstrual cycle. In one obligatory carrier with a normal ratio there was also no fluctuation. It is concluded here that a measurement of the ratio of VIIIc to VIIIag is a valuable adjuvant in genetic counselling in haemophilia.

Problems in the detection of carriers of haemophilia A

Factor VIII activity and factor VIII related--or Willebrand--antigen were studied in 49 known carriers of haemophilia A and 31 normal women, and the data were analysed by four statistical approaches. Sixteen per cent of normals and 18% of carriers were misclassified, overlapping with the other group. Although the percentage of carriers detected is higher when taking into account the results of both biological and immunological factor VIII, it is lower than others recently reported, and the discrepancies between the results obtained are discussed.

Mechanisms and evolutionary origins of variable X-chromosome activity in mammals

The X-chromosome of mammals is remarkable for its variable genetic activity. In somatic cells only a single X-chromosome is active, no matter how many are present, thus providing a dosage compensation mechanism by which males and females effectively have the same gene dosage of X-linked genes. In germ cells, however, it appears that all X-chromosomes present are active. Female germ cells require the presence of two X-chromosomes for normal survival, whereas male germ cells die if they have more than one X-chromosome. This system is found in all eutherian mammals and in marsupials, but is not known in any other animal group. In marsupials the X-chromosome derived from the father seems to be preferentially inactivated, whereas in eutherian mammals that from either parent may be so in different cells of the same animal. The differentiation of a particular X-chromosome as active or inactive is initiated in early embryogeny, and thereafter maintained through all further cell divisions in that individual. The mechanisms by which this is achieved are of great interest in relation to genetic control mechanisms in general. Various recent hypotheses concerning these mechanisms are discussed.

Study of four new kindreds with inherited thyroxine-binding globulin abnormalities. Possible mutations of a single gene locus

Five families with inherited thyroxine-binding globulin (TBG) abnormalities were studied. On the basis of serum thyroxine (T(4))- binding capacity of TBG in affected males, three family types were identified: TBG deficiency, low TBG, and high TBG capacity. In all families evidence for X-linked inheritance was obtained and in one family all criteria establishing this mode of inheritance were met. Only females were heterozygous, exhibiting values intermediate between affected males and normals. Overlap in heterozygotes was most commonly encountered in families with low TBG. QUANTITATIVE VARIATION IN THE SERUM CONCENTRATION OF FUNCTIONALLY NORMAL TBG WAS DEMONSTRATED BY: (a) failure of serum from TBG-deficient subjects to react with anti-TBG antibodies; (b) normal kinetics of T(4) and triiodothyronine-binding to TBG in sera from subjects with low TBG and high TBG capacity; (c) concordance of estimates of TBG concentration by T(4) saturation and by immunological methods; and (d) normal rate of heat inactivation of TBG. No abnormalities in serum transport of cortisol, testosterone, aldosterone, or thyroxine bound to prealbumin could be detected. These observations suggest that all the TBG abnormalities thus far observed reflect mutations at a single X-linked locus involved in the control of TBG synthesis.

Controlling elements in the mouse X-chromosome. 3. Influence upon both parts of an X divided by rearrangement

Data are presented which support the conclusion that in thefleckedtranslocation,T (1; X) Ct, there is a spread of inactivation into both sides of the autosomal region inserted into theX. This would indicate that both parts of the dividedXare subject to theX-inactivation process. The data also demonstrate that the inactivation of autosomal genes lying near each end of the insertion are modified by theX-chromosome controlling element system,Xce. Since the element modifies the heterozygous expression ofX-linked genes on one side of the insertion, it would therefore be expected that it similarly modifies the heterozygous phenotypes of those on the other side. The data thus support the concept that the controlling element is the master gene, receptor site or inactivation centre which regulates theXinactivation process.

Genetic activity of sex chromosomes in germinal cells

If I adhere strictly to the title proposed for me and speak only of the genetic activity of the sex chromosomes in germ cells, there is very little to say. The evidence is necessarily indirect and includes, first, examples of differential behaviour of germ cells of different sex chromosome constitution in situations where competitive proliferation is a possibility, as in some mosaics and chimaeras; and secondly, exceptional species in which the sex chromosome constitution is normally different in germ cells and soma. The species concerned are all mammals. An instance of the first kind is provided by observations made on a 39,X /41,XYY mosaic mouse discovered by chance in the course of an irradiation experiment (Evans, Ford & Searle 1969). All the spermatogonia and spermatocytes examined contained 41 chromosomes, including two Y chromosomes, whereas bone marrow (the only other tissue examined) was mosaic, the probability of difference being due to sampling error being very low. The question, then, was whether the failure to detect mosaicism among the germ cells was a consequence of chance exclusion of the 39, X cell type from the germ line during development, or of differential proliferation and/or survival of 41,XYY germ cells in the testicular environment. The latter interpretation was favoured on the grounds: (1) A 39,X /41,XYY mosaic is likely to have originated by non-disjunction of the Y chromosome at the first cleavage division of a 40,XY zygote, since other theoretically possible modes of origin would require the combination of rare events or other implausible assumptions. (2) Primordial germ cells of the constitution 39, X are capable of reaching the developing gonad and subsequently forming functional oocytes as evidenced by the fertility of 39, X female mice (Russell, Russell & Gower 1959). (3) Nearly all half-and-half coat colour mosaic mutants are also germ cell mosaics (Russell 1964), implying that when two distinct cell lines are present very early in development both lines are likely to be represented among the germ cells

Controlling elements in the mouse X-chromosome. II. Location in the linkage map

The frequency and nature of the changes in ‘state’ of the mouse X-chromosome controlling element (inactivation centre) have been investigated on an inbred background. The results indicate with near-certainty that meiotic crossing over is the responsible mechanism and that the frequency of recombination between theT(1; X)Ctbreakpoint and the locus of the controlling element is approximately 3%. Maize-type ‘changes in state’ may occur under other experimental conditions. The data do not distinguish on which side of the autosomal insertion the element lies but when combined with observations of other investigators suggest that the location must be on theMo-Taside and very close toTa.

Parental influence on X-autosome translocation-induced variegation in the mouse

Females heterozygous for theT(1; X)CtX-autosome translocation tend to have lower levels ofc-variegation when their rearrangedXis inherited from the father rather than from the mother. The difference is not due to a maternal effect. It is postulated that a paternal or parental-source effect, such as that found to modify position effect variegation inDrosophila, is operating but the possibility that a bias in the inactivation of the maternal and paternalXchromosomes is responsible cannot be ruled out.

Controlling elements in the mouse X-chromosome. I. Interaction with the X-linked genes

The mouseX-chromosome controlling elements, detected by their influence on the position effect variegation caused by theX-autosome translocationT(1;X)Ct, have been found to modify the heterozygous phenotypes of twoX-linked genes. It is proposed thatX-inactivation can be incomplete, the level of inactivation or the frequency of cells in which inactivation is incomplete being dependent upon the ‘state’ of the controlling element located in theX. The data suggest that this is a consequence of a reversal, or partial reversal, of inactivation of theXas a whole in some cells rather than a vairable spread of inactivation along the length of theX.

Chromosomal basis of dosage compensation in Drosophila. I. Cellular autonomy of hyperactivity of the male X-chromosome in salivary glands and sex differentiation

Morphology and the rate of RNA synthesis of theX-chromosome inXX/XOmosaic larval salivary glands ofDrosophila melanogasterhave been examined. For this purpose the unstable ring-Xwas utilized to produceXXandXOnuclei in the same pair of glands. The width of theX-chromosome and the left arm of the 3rd chromosome (3L) of larval salivary glands was measured and the rate of RNA synthesis by them was studied upon the use of [3H]uridine autoradiography in suchXX(female) andXO(male) nuclei developing in a female background (i.e. otherwise genotypicallyXX). In such mosaic glands the width of the singleX-chromosome of male nuclei is nearly as great as that of the paired twoX's of female nuclei, as is also the case in normal male (X Y) and female (XX). The singleXof male nuclei synthesizes RNA at a rate equal to that of the paired twoX's of female nuclei and nearly twice that of an unpairedXofXXnuclei. Neither the developmental physiology of the sex nor the proportion ofXOnuclei in a pair of mosaic salivary glands of anXXlarva has any influence on these two characteristics of the maleX-chromosome.

It is suggested that dosage compensation inDrosophilais achieved chiefly, if not fully, by a hyperactivity of the maleX, in contrast to the singleXinactivation in female mammals, that this hyperactivity of the maleXis expressed visibly in the morphology and metabolic activity of theX-chromosome in the larval salivary glands of the male, and that this hyperactivity and therefore dosage compensation inDrosophilain general is not dependent on sex-differentiation, but is a function of the doses of theX-chromosome itself.

Gene action in the mammalian X-chromosome

Contrary to opinions expressed by various authors, the phenotype of heterozygotes for mammalian sex-linked genes gives no support for the Lyon hypothesis (L.H.). Evidence, mainly from the mouse, shows that in such heterozygotes, both alleles act together as in autosomal genes.

In the present paper, it is shown that neither the behaviour of double heterozygotes for sex-linked genes nor that of X-autosome translocations provides independent evidence in favour of the L.H.: in each case, the interpretation depends on that of the behaviour of single heterozygotes and hence fails to discriminate. Moreover, new facts from both types of situation are also contrary to the L.H. In particular, a unified interpretation which fits the behaviour of genes in all known types of X-autosome translocations in the mouse requires the assumption that partial inhibition of gene action happens in both X-chromosomes of mouse females, and presumably the females of other mammals. The new hypothesis is consistent with all relevant genetical facts and, like the L.H., it also accounts for dosage compensation.

Lack of evidence that inactivation of the mouse X-chromosome is incomplete

The fact that the X-linked genes scurfy (sf) and sparse-fur (spf) of the mouse do not produce a mosaic effect in heterozygotes had been taken, by other workers, together with results from X-Autosome translocations, as evidence that inactivation of the mouse X was incomplete. In this paper it is argued that absence of a mosaic effect is not adequate evidence that a gene is not inactivated. The argument was backed by an experiment in which thespfgene was introduced heterozygously into females carrying an X-linked translocation resulting in non-random X-inactivation with the same X active in all cells. When the mutant (spf) allele was on the active X its effect was fully expressed, indicating that the normal allele on the structurally normal inactive X was undergoing inactivation. Argument is further presented that results from X-Autosome translocations do not indicate the degree of completeness of inactivation in a structurally normal X. Hence, there is no evidence that inactivation of the mouse X is incomplete, although evidence from XO females does suggest that it may be incomplete in man.

A study of the nucleolar material in Sciara coprophila

In the polytene chromosomes of Sciara coprophila, in addition to a nucleolus, large numbers of nucleolarlike structures or micronucleoli are formed. A detailed mapping localized the nucleolar organizer at one end of the X chromosome and revealed that approximately 18% of the bands of each chromosome are potentially capable of producing micronucleoli. Most of these sites are in regions known from a previous study to show asynchronous DNA replication: DNA puffs and certain heterochromatic regions. Micronucleoli are rarely found in association with bulbs. The RNA metabolism of the polytene chromosomes during late fourth instar was studied using radioautographic techniques. Isolated glands were incubated in tritiated uridine for 10 to 30 min, and radioautographs were made of squash preparations. Despite the wide range of variation found among different larval cultures, the following pattern was observed. Just prior to and at the beginning of DNA puff formation, a period of intense extrachromosomal nucleolar and micronucleolar RNA synthesis occurs. After maximal development of the DNA puffs, the synthesis of extrachromosomal RNA is at a low point, while incorporation into bulbs and DNA puffs remains high. With the onset of the prepupal stage, all nuclear RNA synthesis ceases.

Chromosome Changes Induced by Infections in Tissues of Rhynchosciara angelae

The main effects of two infections, one by a protozoan and the other by a virus, in cells of Rhynchosciara angelae (Diptera, Sciaridae) are an increase in cell size and changes in the size, shape, and behavior of the chromosomes. The X chromosome of some cells reacts differently from the autosome to the protozoan infection. Some chromosomes show specific, easily traceable points after infection by the virus. Some of the effects of these infections may be similar to the effects of infective agents in other organisms.