Deletion in the Y chromosome of B10.BR-Ydel mice alters transcription from MSYq genes and has moderate effect on DNA methylation.

B10.BR-Ydel male mice with large deletion in the male-specific region of the Y chromosome long arm (MSYq) are very useful experimental model which requires, however, more detailed characterization. In the present study, the influence of the deletion on transcript levels of MSYq genes (Ssty1, Ssty2, Sly, Srsy, Asty, Orly) and homologous to them X-linked genes (Sstx, Slx, Slxl1, Srsx) was assessed. Quantitative PCR analysis showed that in testes of B10.BR-Ydel males activity of Ssty1 is unchanged, but transcription from all other MSYq genes is highly reduced and reaches from 59 % to only 5 % of the control levels. The decrease in expression of MSYq genes is accompanied by the two-fold increase in expression of Slx and Slxl1 genes. This is the first functional characterization of the deletion in B10.BR-Ydel strain. Another aim of the study was to reveal the mechanism through which deleted Y chromosome of B10.BR-Ydel males could alter phenotype of their female progeny, what was documented in our previous works. Epigenetic inheritance hypothesis was tested by microarray analysis of DNA methylation in B10.BR-Ydel and control B10.BR sperm. The assessment revealed moderate differences and allowed concluding that the mutated Y chromosome can influence traits of females from the next generation partially through altering sperm DNA methylation, but probably some additional mechanisms are engaged here. Breeding data indicate that feminization of pre- and neonatal environment in which next generation females develop is one of such additional mechanisms.

The contribution of p53 and Y chromosome long arm genes to regulation of apoptosis in mouse testis.

Apoptosis of excessive or defective germ cells is a natural process occurring in mammalian testes. Tumour suppressor protein p53 is involved in this process both in developing and adult male gonads. Its contribution to testicular physiology is known to be modified by genetic background. The aim of this study was to evaluate the combined influence of the p53 and Y chromosome long arm genes on male germ cell apoptosis. Knockout of the transformation related protein 53 (Trp53) gene was introduced into congenic strains: B10.BR (intact Y chromosome) and B10.BR-Ydel (Y chromosome with a deletion in the long arm). The level of apoptosis in the testes of 19-day-old and 3-month-old male mice was determined using the terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate in situ nick-end labelling (TUNEL) method. The study revealed that although p53 is involved in germ cell apoptosis in peripubertal testes, this process can also be mediated by p53-independent mechanisms. However, activation of p53-independent apoptotic pathways in the absence of the p53 protein requires engagement of the multicopy Yq genes and was not observed in gonads of B10.BR-Ydel-p53-/- males. The role of Yq genes in the regulation of testicular apoptosis seems to be restricted to the initial wave of spermatogenesis and is not evident in adult gonads. The study confirmed, instead, that p53 does participate in spontaneous apoptosis in mature testes.

Aging deteriorates quality of sperm produced by male mice with partial Yq deletion.

The aim of the study was to assess the cumulative effects of aging and Y-chromosome long arm deletion on sperm quality parameters. Motility, mitochondrial activity, and head morphology were evaluated for sperm of 3- and 12-month-old males from B10.BR-Ydel and B10.BR congenic mouse strains. The study revealed that quality and fertilizing potential of sperm produced by younger and older B10.BR males persist on similar levels, but worsen significantly with age of B10.BR-Ydel males. The findings imply that partial Yq deletions might be more harmful for spermiogenesis in advancing age and may be applicable to other species including humans. ABBREVIATIONS: AZF: azoospermia factor; MSYq: male-specific region of the Y-chromosome long arm.

Increased progesterone production in cumulus-oocyte complexes of female mice sired by males with the Y-chromosome long arm deletion and its potential influence on fertilization efficiency.

It was revealed previously that B10.BR(Y(del)) females sired by males with the Y-chromosome long arm deletion differ from genetically identical B10.BR females sired by males with the intact Y chromosome. This is interpreted as a result of different epigenetic information which females of both groups inherit from their fathers. In the following study, we show that cumulus-oocyte complexes ovulated by B10.BR(Y(del)) females synthesize increased amounts of progesterone, which is important sperm stimulator. Because their extracellular matrix is excessively firm, the increased progesterone secretion belongs presumably to factors that compensate this feature enabling unchanged fertilization ratios. Described compensatory mechanism can act only on sperm of high quality, presenting proper receptors. Indeed, low proportion of sperm of Y(del) males that poorly fertilize B10.BR(Y(del)) oocytes demonstrates positive staining of membrane progesterone receptors. This proportion is significantly higher for sperm of control males that fertilize B10.BR(Y(del)) and B10.BR oocytes with the same efficiency.

Curcumin influences semen quality parameters and reverses the di(2-ethylhexyl)phthalate (DEHP)-induced testicular damage in mice.

BACKGROUND: Curcumin is a phytochemical derived from rhizome of turmeric Curcuma longa, present in the curry spice. Recently, it has attracted the attention of researchers and clinicians as an anti-inflammatory and anti-oxidant agent with a potential use in therapy of many diseases with an inflammatory component. Interestingly, curcumin despite its very low bioavailability showed protective activity against many organ lesions. METHODS: In the present study we investigated the effects of curcumin treatment on mice semen quality parameters in vitro and on semen and testicular damage induced by di(2-ethylhexyl)phthalate in vivo. RESULTS: The study demonstrated protective effects of low concentrations (1-50 µM) of curcumin on mouse sperm motility in vitro and on DEHP-induced damage of seminiferous tubules in testes and its ability to diminish the decrease in sperm motility in vivo. In contrast, curcumin used in high concentration (100 µM) decreased sperm motility and viability in vitro. CONCLUSION: The effects of curcumin were dependent on its concentration. In male germ cells in vivo the protective effect was seen despite the low bioavailability of curcumin. In contrast, high, unattainable in the organism, concentration of curcumin had a cytotoxic effect on male reproductive cells in vitro. Curcumin also had a protective effect against the harmful impact of DEHP on the male reproductive system.

Increased prostaglandin E2-EP2 signalling in cumulus cells of female mice sired by males with the Y-chromosome long-arm deletion.

Cumuli oophori surrounding ovulated oocytes of B10.BR(Y(del)) females (sired by males with the Y-chromosome long-arm deletion) are more resistant to hyaluronidase digestion than cumuli oophori around eggs of genetically identical females but sired by males with the intact Y chromosome (B10.BR). This has been interpreted as a result of differences in paternal genome imprinting, which females of both groups inherit from their fathers. The following study shows that it is not hyaluronan, but rather excessive protein concentration, that makes the cumulus extracellular matrix of B10.BR(Y(del)) oocytes more resistant to enzymatic treatment. It was revealed, additionally, that cumulus cells around ovulating oocytes of B10.BR(Y(del)) females display higher surface accumulation of prostaglandin EP2 subtype receptors and higher expression of the Ptgs2 gene (encoding a rate-limiting enzyme of prostaglandin E2 synthesis) in relation to the cells of control B10.BR females. The expression levels of the prostaglandin-dependent Tnfaip6 and Ccl2 genes were also altered in B10.BR(Y(del)) cumulus cells in a manner indicating increased prostaglandin signalling. The study provides further evidence for the divergence in reproductive phenotypes between B10.BR and B10.BR(Y(del)) female mice. It supports the hypothesis that genes of the Y-chromosome long arm may be involved in establishment of epigenetic marks in X-bearing spermatozoa.

Is p53 controlling spermatogenesis in male mice with the deletion on the Y chromosome?

The aim of the study was to evaluate the influence of the chromosome Y structure and Trp53 genotype on semen quality parameters. Mice with partial deletion of the Y chromosome (B10.BR-Ydel) have severely altered sperm head morphology when compared with males that possess the complete Y chromosome (B10.BR). Control males from B10.BR and B10.BR-Ydel mice, and mutant males from B10.BR-p53 -/- and B10.BR-Ydel-p53 -/- experimental groups were used. We assessed testis weight, sperm head abnormalities, viability of spermatozoa (eosin test), percentage of motile and immature sperm, and performed a hypo-osmotic test to detect abnormal tail membrane integrity. Sperm morphology and maturation were controlled by the genes within the deleted region of the Y chromosome. Testis weight was higher in the mutants than in the control males, possibly due to cell accumulation in Trp53-deficient males as the concentration of sperm was significantly increased in the mutants. An elevated percentage of abnormal sperm was noted in B10.BR-p53 -/- and B10.BR-Ydel-p53 -/- male mice. We suggest that, in Trp53-deficient mice, the sperm cells that escape apoptosis are the ones that have abnormal morphology. The only sperm quality parameter affected by the interplay between Trp53 and chromosome Y genes was sperm motility, which was elevated in B10.BR-p53 -/- males, but remained unchanged in B10.BR-Ydel-p53 -/- males.

Can the partial deletion in the Y chromosome of male mice affect the reproductive efficiency of their daughters?

It has been previously shown that cumuli oophori around ovulated oocytes of B10.BR-Y(del) female mice (sired by males with the deleted Y chromosome) are more resistant to enzymatic treatment than cumuli oophori around eggs of control B10.BR females (having fathers with the intact Y chromosome). This can imply that some genes which influence the establishment of the imprinting pattern in male gametes are located in the region covered by the deletion. We hypothesize that the Y-dependent imprinting pattern, inherited by female offspring, affects stability of periovum layers within them. In the present study, cumulus-oocyte complexes ovulated by females from consomic strains: DBA, DBA-Y(BR), DBA-Y(del), and CBA, CBA-Y(BR), CBA-Y(del) were tested for their susceptibility to hyaluronidase digestion. The mean times for dispersal of cumulus cells surrounding oocytes of females from the backcross lines were convergent with the times typical for oocytes from strains being the donors of the Y chromosome (B10.BR or B10.BR-Y(del)) and differed clearly from pure DBA and CBA strains. It confirmed previous findings that Y chromosomes of fathers influence the properties of cumulus-oocyte complexes ovulated by their daughters. This influence is definitely stronger than the influence of the genetic background. Additionally, it was demonstrated that the cumuli oophori surrounding oocytes of B10.BR-Y(del) females exhibit increased resistance to penetration by spermatozoa in vitro, in comparison to the control B10.BR strain. This regularity was reflected in the decreased proportion of fertilized ova recovered from oviducts of B10.BR-Y(del) females mated with B10.BR-Y(del) males and in the lower litter sizes recorded for these pairs. The excessive stability of cumuli oophori typical for oocytes of females having Y(del) fathers may negatively affect their fertility, if they have partners producing poor quality sperm.

Semen quality parameters and embryo lethality in mice deficient for Trp53 protein.

Trp53 is a protein which is able to control semen parameters in mice, but the extent of that control depends on the genetic background of the mouse strain. Males from C57BL/6Kw, 129/Sv, C57BL×129 -p53+/+ (wild type controls) and C57BL×129-p53-/- (mutants) strains were used in the study, and histology and light microscopy were applied to evaluate the influence of genetic background and Trp53 (p53) genotype on testes morphology and semen quality in male mice. We showed that sperm head morphology, maturity and tail membrane integrity were controlled only by the genetic background of C57BL/6Kw and 129/Sv males, while testes weight and sperm concentration depended on both the genetic background and p53 genotype. Cell accumulation in seminiferous tubules may be responsible for heavier testes of p53-deficient males. In addition, to examine the effect of sex and p53 genotype on embryo lethality, pairs of control (C57BL×129-p53+/+) and heterozygous (C57BL×129-p53+/-) mice were examined. Before day 7 post coitum (dpc), female and male embryos were equally resorbed in both crosses types. After 7 dpc, preferential female embryo lethality in the heterozygote pairs was responsible for the skewed sex ratio in their progeny. Also, mutant female and male newborns were underrepresented in the litters of the heterozygous breeding pairs.

Alterations in the expression of the Atp7a gene in the early postnatal development of the mosaic mutant mice (Atp7a mo-ms) - An animal model for Menkes disease.

Copper is a trace element that is essential for the normal growth and development of all living organisms. In mammals, the ATP7A Cu-transporting ATPase is a key protein that is required for the maintenance of copper homeostasis. In both humans and mice, the ATP7A protein is coded by the X-linked ATP7A/Atp7a gene. Disturbances in copper metabolism caused by mutations in the ATP7A/Atp7a gene lead to severe metabolic syndromes Menkes disease in humans and the lethal mottled phenotype in mice. Mosaic is one of numerous mottled mutations and may serve as a model for a severe Menkes disease variant. In Menkes patients, mutations in the ATP7A gene often result in a decreased level of the normal ATP7A protein. The aim of this study was to analyse the expression of the Atp7a gene in mosaic mutants in early postnatal development, a critical period for starting copper supplementation therapy in both Menkes patients and mutant mice. Using real-time quantitative RT-PCR, we analysed the expression of the Atp7a gene in the brain, kidney and liver of newborn (P0.5) and suckling (P14) mice. Our results indicate that in mosaic P0.5 mutants, the Atp7a mRNA level is decreased in all analysed organs in comparison with wild-type animals. In two week-old mutants, a significant decrease was observed only in the kidney. In contrast, their hepatic level of Atp7a tended to be higher than in wild-type mice. We speculate that disturbance in the expression of the Atp7a gene and, consequently, change in the copper concentration of the organs, may contribute to the early fatal outcome of mosaic males.

Correlation of centromeric heterochromatin C-band polymorphism with breeding failure in mice.

The aim of the present study was to test the hypothesis about the relation between segregation of chromosomes 14 and 18 and the deterioration of mouse fertility and vitality. The analysis was possible because C-banding on chromosome 14 and chromosome 18 of the CBA/Kw and KE strains show size polymorphism. A small sized C-band on chromosome 14 is characteristic for the CBA/Kw mice, while the KE mice show small C-bands on chromosomes 18. Thus, if fertility parameters are affected in a centromere-dependent manner, we should observe non-random inheritance of both chromosome pairs in recombinant inbred (RI) strains. The results showed statistically significant preferential segregation of chromosomes 14 and 18 with small C-bands. Most of the RI strains inherited chromosome 14 from the CBA/Kw strain and chromosome 18 from the KE strain, and did not manifest a deterioration of fertility and vitality. On the contrary, RI strains that inherited chromosomes 14 and 18 from one of the parental strains, particularly the KE strain, stopped breeding or had difficulties in producing the next generation.

Copper metabolism disorders affect testes structure and gamete quality in male mice.

In the present study, animals with a genetic defect in copper metabolism were used as a model organism to study the role of copper in reproduction and to determine whether the disturbances in copper and zinc metabolism affect the testicular tissue and gamete quality in males. Mice with an X-linked mosaic mutation (Atp7a(mo-ms)) exhibit pathological features characteristic of affected copper metabolism. This mutation usually leads to lethality of the mutant males which generally expire on about day 16. Only 4% of mutant animals survive the critical period, achieve maturity, and become fertile. To improve the mutants' viability they were treated with subcutaneous injections of cupric chloride. We measured copper and zinc concentration in the gonads of young (14-day-old) and adult (5-month-old) mutant and control males. Results indicate that copper content was increased but zinc was decreased in the mutant testes. Analysis of the morphology of the testis of the young animals indicate that apoptosis (characteristic for the gonads of young males) was increased in the gonads of the 14-day-old mutants. This process was less advanced in the group of 14-day-old copper treated control males. Apoptosis was also increased in the testes of the adult mutants. Moreover in adult mutants we observed pathological changes in testes morphology (atrophic and sclerotic tubules). Copper and zinc disorders also negatively influenced semen quality parameters, including sperm motility, head morphology, tail cytoplasmic membrane integrity, and number of viable spermatozoa. Poor semen quality of the mutant males seems to be responsible for affected in vivo fertilization efficiency. Treatment with cupric chloride did not influence semen quality except in maturation rate, which was even slower in both mutant and control males after treatment. Additionally, in mutants, copulatory plugs and fertile copulation outcome were decreased after copper treatment.

Sperm mitochondria diaphorase activity--a gene mapping study of recombinant inbred strains of mice.

In order to study the genetic control of semen quality parameters, we derived a set of recombinant inbred (RI) mice from crosses between two inbred strains, KE and CBA/Kw, which differ significantly in gamete quality and fertility parameters. In this work, we used male mice from the two parental strains and from ten RI strains to map genes controlling quantitative traits such as sperm mitochondrial diaphorase activity, and assessed the correlation between this trait, sperm motility and in vivo fertilization efficiency. We analyzed sperm mitochondrial dehydrogenase (diaphorase) activity (NADH-dependent NBT assay) cytochemically by means of computerized image densitometry and obtained values for four parameters: 1) integrated optical density (IOD) for all pixels of the midpiece, 2) mean optical density (MOD) for the midpiece pixels, 3) length of sperm midpiece and 4) area of sperm midpiece. Polymorphic microsatellite marker profiles were prepared for 20 mouse chromosomes in the ten RI strains. We used Map Manager QTX software to correlate the strain distribution patterns (SDPs) of the four measured parameters with the SDPs of the analyzed markers. Hypothetical genes modifying diaphorase activity were mapped to chromosomal region 19q43-19q47, containing, for example, Poll, Sfxn2, Cyp17a1 and Usmg5 genes. Chromosomal regions 18q44 and 18q49-18q80 also showed correlation with the SDPs of diaphorase activity. Katnal2, Me2 and StARD6 candidate genes were proposed from this region. Diaphorase activity in the mouse sperm midpiece did not correlate with in vivo fertilization efficiency, but was negatively correlated with the linearity and straightness of sperm movement.

Effects of copper supplementation on the structure and content of elements in kidneys of mosaic mutant mice.

Menkes disease is an effect of ATP7A gene mutation in humans, coding the Cu-ATP-ase which is essential in intestinal copper absorption and its subsequent transfer to circulation. This mutation results in a deficiency of copper in all tissues except the epithelia of intestine and kidney tubules. Subcutaneous injection of copper ions is the main therapy for Menkes patients. Mosaic (Atp7a(mo-ms)) mice closely simulate the situation in Menkes disease. The aim of this study was to evaluate the changes in structure and element content in kidneys of mosaic mice after copper supplementation. Hematoxylin-eosin staining was used to analyze tissue morphology and atomic absorption spectrometry to estimate Cu and Zn content. X-ray microanalysis was performed to measure Na, Mg, P, Cl, and K content in the cells of the proximal and distal tubules. Copper administration lengthened the lifespan of the mutants but led to its high accumulation and results in severe kidney damage. Karyomegalia, necrosis of tubular and Bowman's capsule epithelium, lesions, and atrophy of glomeruli were observed in the treated mutants. Copper treatment afterwards led to sclerosis of glomeruli and tubules enhanced proliferation of epithelial cells and formation of both polycystic and papillary carcinoma patterns in kidney. We suggest that copper excess may impair the activity of Na(+)/K(+) ATP-ase in renal tubules of ms/- males. The content of Mg, P, and Cl in kidneys in mutants was also changed after copper administration.

Semen quantity and quality correlate with bank vole males' social status.

Laboratory studies reveal that in several rodent species the females prefer dominant males as mating partners. Here we investigate the correlation between bank vole males' social rank and their sperm quality and quantity. We used agonistic encounters to determine males' social status. Sperm quality was assessed by its motility, viability, maturity, morphology and sperm tail membrane integrity. Relatively more dominant males were heavier than males of lower social status. The males' social position affected the testes, seminal vesicles and coagulation gland development. The weights of these reproductive organs were significantly higher in more dominant males than in more subordinate males. Sperm counts and the values of the other parameters describing sperm quality were higher in high-ranking males than in subordinates. Our results suggest that bank vole females benefit from choosing and mating with high-ranking males by obtaining more and better-quality sperm.

Impaired growth hormone-releasing hormone neurons ultrastructure and peptide accumulation in the arcuate nucleus of mosaic mice with altered copper metabolism.

A progressive decrease in body weight and retarded linear growth observed in mosaic male mice with the mutation linked to X-chromosome (Atp7a(mo-ms)) raised the question whether hypophysiotropic growth axis activity may be affected in these animals. A pathologically developed median eminence ultrastructure with very low somatostatin accumulation as well as an intensive phagocytosis of growth hormone cells observed in the anterior pituitary gland raised the question whether hypothalamic growth hormone-releasing hormone (GHRH) neuronal network is also affected in mosaic mice. In this study an arcuate nucleus GHRH neurons ultrastructure as well as GHRH peptide accumulation in normal and mutant mice were compared. An electron microscopic immunocytochemical method with colloidal-gold labeling was applied to compare the ultrastructural morphology of GHRH neuron and intracellular GHRH peptide distribution. Mosaic mice exhibited a pathologically developed ultrastructure of arcuate nucleus GHRH neurons, defective intracellular peptide localization as well as reduced peptide storage. Obtained results support the crucial role of unaltered copper metabolism in physiological development of hypophysiotropic growth axis activity. Consequently, a pathologically developed GHRH hypothalamic network may impact progressive decrease in body weight and retarded length growth observed in mosaic male mice.

Genetic control of gamete quality in the mouse--a tribute to Halina Krzanowska.

In this article, we summarise the principal research findings of the distinguished Polish scientist, Professor Halina Krzanowska, related to the genetic control of mammalian gamete quality. During the early stages of her career, Halina Krzanowska conducted experiments on poultry and then she moved on to work on mice. All her research on gamete quality was conducted on the research models, consomic, congenic and recombinant inbred strains, which Krzanowska developed herself. These models differed mostly in their fertility. Krzanowska was one of the first researchers to demonstrate the influence of chromosome Y on the morphology of mice spermatozoa. She also showed that the uterotubal junction is in vivo a selection barrier for the morphologically abnormal spermatozoa, whereas in vitro abnormal spermatozoa are able to participate in fertilization, the function of selective barrier being performed by the granulosa cell layer and the zona pellucida. Another model which Krzanowska produced were chimaeras, which she used to find out if the percentage of abnormal spermatozoa and the efficiency of fertilization are determined by germ cells themselves or by environmental factors and she discovered that sperm head shape, the proportion of abnormal sperm and fertilizing capacity are determined mainly by the genotype of germ cells and only minimally by environmental factors.

Gene mapping of sperm quality parameters in recombinant inbred strains of mice.

The aim of this study was to map chromosomal regions containing hypothetical genes responsible for the following parameters of mouse semen quality: (1) the percentage of sperm with abnormal head morphology, (2) the level of dead spermatozoa, (3) the percentage of sperm tails with residual cytoplasmic droplets, and (4) the percentage of sperm with impaired sperm tail membrane integrity. We also analyzed any possible correlations between these parameters. The most appropriate animal model for mapping genes controlling quantitative traits (QTL, quantitative trait locus) is a set of recombinant inbred (RI) strains. The set of RI strains used in this study was derived from crosses between two inbred mouse strains, KE and CBA/Kw, which differ significantly in fertility parameters and gamete quality. We analyzed the four parameters of sperm quality in male mice from two parental strains and from 12 RI strains. The strain distribution pattern (SDP) of 187 polymorphic microsatellite markers was prepared for 20 chromosomes of the mouse genome in 12 RI strains. We correlated the SDP of these markers with the values of sperm quality parameters, using MapManager QTX software (ver. b18). The mapping procedure indicated that the percentage of sperm with abnormal head morphology is controlled by gene(s) located in chromosomal regions 11q24, 11q31 and 6q15.6. There was also a strong correlation between male body weight and the hypothetical gene(s) in chromosomal region 18q47. A detailed analysis of the genes located in these regions enabled us to prepare a list of candidate genes. We discuss the basis of the correlation between the measured parameters.

Testicular morphology and expression of aromatase in testes of mice with the mosaic mutation (Atp7a mo-ms).

The aim of this study was to determine whether testicular cells of mice with the mosaic mutation, associated with abnormal copper metabolism, are able to aromatize androgens to estrogens, and what is the putative role of estrogens in the gonad of the mutant male. Mosaic is a lethal mutation; affected males usually die on about day 16. Those, which survive to reach sexual maturity, are valuable research subjects. In testes of young and adult mutants, histological analysis revealed the presence of many degenerating seminiferous tubules besides normal-looking ones. Additionally, high numbers of apoptotic germ cells were observed, especially in young mutants when compared with the controls. Positive immunostaining for aromatase was found in cultured Leydig cells and testicular sections of both control and mutant males. The intensity of immunostaining was always stronger in the mosaic mice. In both groups, Western-blot analysis revealed the presence of aromatase protein as a single band of approximately 55 kDa. In the mosaic males, levels of testosterone in cultured Leydig cells, whole testes, and in blood plasma were lower than in those of the respective controls. On the contrary, estradiol concentrations were always higher in the mutants. Both in vivo and in vitro studies indicate that morphological and functional changes in the testes of the mosaic mice mainly result from defective copper metabolism. The higher level of endogenous estrogens can additionally enhance morphological alterations within the testes. It seems also likely that excess estrogens may affect the survival rate of the mosaic males.

The influence of the deletion on the long arm of the Y chromosome on sperm motility in mice.

The multicopy region on the long arm of the mouse Y chromosome contains four known genes. There are evidences that deletions in this region lead to decrease of sperm quality in mutant mice. Male mice completely lacking this region are infertile. Here we report results obtained by using the computer assisted semen analysis system (CASA), describing the movement parameters of spermatozoa from mutant males with partial deletion on the long arm of the Y chromosome (B10. BR-Y(del)). First we have determined that genes necessary for spermiogenesis and located in this region are still active in mutants, than we have compared the sperm movement of mutants and control animals. This analysis revealed that the Yq deletion affects: velocity parameters (VAP, VCL, VSL), parameters describing sperm head activity during movement (ALH and BCF) and linearity (LIN) of movement. Our findings indicate that sperm movement is controlled by genes located in the long arm of the Y chromosome.