The molecular basis of "curlicue": a sperm motility abnormality linked to the sterility of t haplotype homozygous male mice.

The t complex, a variant region of chromatin occupying approximately 40-million base pairs of proximal chromosome 17, exists in natural populations of wild mice of the Mus musculus species as a family of homologues called t haplotypes (t). Relative to wild-type (+) homologues, all t haplotypes share four large non-overlapping inversions, spanning 95% of the region, leading to intra-inversion recombination suppression in +/t heterozygotes. Non-lethal t homozygous males or complementing recessive lethal t doubly heterozygous males (hereafter both abbreviated "t/t males") are invariably and completely sterile, due to expression of several sperm function abnormalities. One of these traits, "curlicue", describes a condition in which spermatozoa from t/t males fail to reach the site of fertilization in vivo because they exhibit a severe loss of vigorous forward motility due to the chronic negative curvature of their flagella. Current data indicate that "curlicue" is the complex phenotypic reflection of the expression of three or more mutations clustered in the distal one-third of the largest and most-distal t complex inversion, In(17)4. From proximal to distal, candidates include Dnahc8, Tsga2 and Tctex5. Interestingly, new results from high-resolution intra-inversion genetic mapping and protein localization studies suggest that the products of the distal two candidates, Tsga2 and Tctex5, might play synergic roles in the expression of both the "curlicue" motility abnormality and the "stop" sperm-egg interaction aberration, regarded as functionally unrelated traits.

Genes in the first and fourth inversions of the mouse t complex synergistically mediate sperm capacitation and interactions with the oocyte.

The t haplotypes (t) are recent evolutionary derivatives of an alternate form of the mouse t complex region located at the proximal end of chromosome 17. This variant form of approximately 1% of the mouse genome is a source of mutations altering numerous sperm functions crucial for fertilization. Males that carry two t haplotypes (t/t) are invariably sterile. t haplotypes contain four inversions relative to the wild-type t complex (+), so that in matings involving a +/t heterozygote, t is usually transmitted as a single unit. However, rare recombinants have been recovered, which carry only part of the t genotype and express only some of the t-dependent phenotypes. Use of these partial t haplotypes in genetic crosses has resulted in the general location of the two major t male sterility factors, S1 and S2, within inversions 1 and 4, respectively. Since sterility can result from a plethora of sperm defects, we have made a detailed study of various functional parameters of sperm from mice carrying S1 or S2 heterozygously or homozygously or in combination. Both S1 and S2 contain mutations altering sperm functions, including motility, capacitation, binding to the zona pellucida, binding to the oocyte membrane, and penetration of the zona pellucida-free oocyte. Therefore it seems clear that each of these factors contains multiple genes contributing to sterility. Furthermore, our results indicate that genes within S1 interact with genes in S2 for all sperm functions examined. However, S1 and S2 genes affecting motility interact in a purely additive fashion, while S1 and S2 genes affecting most other sperm characteristics interact in a synergistic manner. Additionally, the patterns of synergism between S1 and S2 for abnormalities in capacitation, sperm-oolemma binding, and zona-free oocyte penetration are nearly identical. This suggests that these three defects are caused by mutation of the same gene within each sterility factor. These findings will not only be instrumental in matching the various t haplotype sperm defects to candidate genes for S1 and S2, but will facilitate a more comprehensive understanding of the cellular and genetic mechanisms underlying t haplotype male sterility.

An axonemal dynein at the Hybrid Sterility 6 locus: implications for t haplotype-specific male sterility and the evolution of species barriers.

Poor sperm motility characterized by a distinct aberration in flagellar waveform known as "curlicue" is a hallmark of t haplotype (t) homozygous male sterility. Previous studies have localized "curlicue" and a flagellar developmental defect, "whipless", to the Hybrid Sterility 6 locus (Hst6), between the markers Pim1 and Crya1. More recent heterospecific breeding experiments between Mus spretus (Spretus) and Mus musculus domesticus (Domesticus) have mapped the primary source(s) of both "curlicue" and "whipless" to a small sub-locus of Hst6, Curlicue a (Ccua). Here we report the complete physical isolation of the Ccua locus and the identification of a candidate gene for expression of both "whipless" and "curlicue" at its proximal end, an axonemal dynein heavy chain gene, Dnahc8, formerly mapped by interspecific backcross analysis near Pim1. Dnahc8 mRNA expression commences in the Domesticus wild-type testis just prior to flagellar assembly and is testis-specific in the adult male. However, expression of Dnahc8 is not readily evident in the testis of either Spretus or "whipless" animals (Domesticus males homozygous for the Spretus allele of Dnahc8). Our results argue that Dnahc8 is fundamental to flagellar organization and function in Domesticus, but not Spretus, and suggest that Dnahc8 is integral to both Hst6- and t-specific male infertility.

Mapping and cloning recombinant breakpoints demarcating the hybrid sterility 6-specific sperm tail assembly defect.

Variants of the mouse t complex known as t haplotypes (t) express factors that perturb sperm differentiation, resulting in the non-Mendelian transmission of t from +/t heterozygous males and the sterility of t/t homozygous males. Previous studies of mice carrying heterospecific combinations of the t complex have revealed a 1-cM candidate locus, Hst6, for the distal-most of these factors, Tcd/Tcs2. Males heterozygous for the M. spretus allele of Hst6 and a t haplotype (Hst6(s)/t) are sterile, expressing an abnormality in sperm flagellar curvature ("curlicue") indistinguishable from one exhibited by sperm from t/t homozygotes. Hst6(s)/Hst6(s) males are also sterile; however, sperm produced by these males are completely immotile owing to the absence of assembled flagella. Recent studies have shown that the complete presentation of "curlicue" derives from expression of at least two factors within the locus, Curlicue a (Ccua) proximally and Curlicue b (Ccub) distally, with a factor affecting sperm-oolemma penetration, Stop1p, mapping between them. In the present report, we have examined expression of the Hst6-specific flagellar assembly phenotype in sperm from mice homozygous for M. spretus-M. m. domesticus recombinant Chr 17 homologs whose breakpoints map within the Hst6 locus. SSLP analysis of these homologs has demonstrated that the flagellar assembly defect maps to less than 0.2 cM between D17Mit61 and D17Mit135, coincident with Ccua. SSR content analysis of 23 BACs mapping to four contigs within the Hst6 locus has resulted in isolation of proximal and distal recombinant breakpoints circumscribing the flagellar assembly phenotype/Ccua factor. In addition, we have provided increased high-resolution mapping of the Stop1p and Ccub factors. These new data enhance our ability to isolate and characterize candidates for Tcd/Tcs2.

High-resolution mapping of sperm function defects in the t complex fourth inversion.

Structural variants of the mouse Chr 17-specific t complex, known as t haplotypes, express factors that alter the ability of sperm to carry out their roles in the normal fertilization process. In previous studies of males carrying heterospecific combinations of the t complex, we discovered a unique M. spretus/t haplotype phenotype of male sterility. In additional studies with mice carrying a series of M. spretus-M. m. domesticus recombinant Chr 17 homologs and a complete t haplotype (S-+/t), we monitored physiological aspects of sperm function to map a locus (Hst6) responsible for expression of the t-specific "curlicue" sperm flagellar curvature phenotype to 1 cM within the fourth inversion of the t complex. In the present report, we quantitatively analyze the in vitro capability of sperm from mice with similar S-+/t Chr 17 genotypes to fertilize zona pellucida-free mouse eggs. The results identify a locus, Stop1, mapping distal to Pim1, with acute effects on the ability of sperm to penetrate the oolemma. The data suggest that Stop1 is a complex locus consisting of at least two genetic elements, a proximal one overlapping the Hst6 locus, and another, distal to the Hst6 locus. Further quantitative analyses of the "curlicue" phenotype produced by sperm derived from these same animals indicate that expression of this chronic flagellar curvature phenotype also derives from at least two elements, both mapping within the Hst6 locus. Thus, these studies provide higher resolution mapping of the molecular basis of t haplotype-specific sperm dysfunction emanating from In(17)4.

Expression of the c-kit gene is critical for migration of neonatal rat gonocytes in vitro.

Rat gonocytes migrate to the basement membrane during the first postnatal week, a change in position crucial for their survival. These cells express the c-kit gene from the day of birth through Day 5 in vivo and develop the ability to migrate in Sertoli cell-gonocyte cocultures. In this study, we asked whether c-kit expression and synthesis of Kit protein are required for pseudopod production by gonocytes in vitro. To determine whether gonocyte migration in vitro is invariably accompanied by c-kit expression, we quantified percentages of gonocytes expressing c-kit with increasing time in vitro and correlated these data with pseudopod development by individual cells. We also determined the effect of exposure to Kit antibodies on gonocyte migration in vitro, and, conversely, asked whether addition of exogenous stem cell factor (SCF), the Kit ligand, stimulates pseudopod development. We found that 1) increasing numbers of gonocytes express c-kit with increasing time in vitro; 2) once these cells begin migrating in vitro, the appearance of a pseudopod on a gonocyte is absolutely correlated with kit expression by that cell; 3) incubating cocultures with Kit antibodies significantly reduces the number of cells with pseudopods, without any detectable decrease in numbers of gonocytes; and 4) addition of exogenous SCF to cocultures prepared on Day 5 results in a transient but significant increase in the percentage of gonocytes with pseudopods even though we found that Sertoli cells in the cultures produce endogenous SCF. Thus, our findings provide evidence to support a role for c-kit expression by neonatal gonocytes and, presumably, SCF expression by neonatal Sertoli cells in stimulating migration of these germ cells in vitro.

Hst7: a male sterility mutation perturbing sperm motility, flagellar assembly, and mitochondrial sheath differentiation.

Hst7, a mouse hybrid sterility locus, has been mapped in close linkage to four other hybrid sterility loci, on proximal chromosome 17 within the t complex. When an allele (s) of Hst7 from the species Mus spretus is crossed into the Mus musculus domesticus (laboratory mouse) background, all male offspring are sterile. This occurs regardless of whether the Hst7 allele on the other chromosome 17 homolog is wild-type (+) or an allele (t) derived from the structurally variant homolog known as a t haplotype. Males of the Hst7 genotype s/+ produce sperm that, after release from the cauda epididymis, display moderate asthenospermia (straight line velocity = 49 +/- 4 microm/second, significantly lower than 102 +/- 7 microm/second for congenic wild-type controls) and normal morphology. However, males of the Hst7 genotype s/t produce sperm whose forward movement is below the detectable limit of the sperm motion analysis system. In addition, these sperm exhibit a variety of flagellar abnormalities, with about one third having normal heads attached to sacklike caudal regions. These sacks consist of membrane-delimited cytoplasm containing disorganized and/or misshapen axonemal elements. The remainder of the sperm from s/t mice have flagella with seemingly normal axonemes, although many exhibit enlarged areas of cytoplasm in their midpieces with extra layers of misaligned mitochondria. The s/t sperm mitochondria also display diffuse and vacuolated matrices reminiscent of meiotic germ cell and spermatid mitochondria. Observations of developing spermatids in the s/t testis reveal an unusual phenotype in which gaps of varying length occur in the mitochondrial wrapping of the midpiece. These data suggest that both the s and t alleles of Hst7 are defective alleles that contribute differentially to the severe asthenospermia phenotype and interact genetically to perturb flagellar development.

Sperm from mice carrying two t haplotypes do not possess a tyrosine phosphorylated form of hexokinase.

Mouse sperm contain a tyrosine phosphorylated form of hexokinase type 1 (HK1; Kalab et al., 1994: J Biol Chem 269:3810-3817) that has properties consistent with an integral plasma membrane protein. Furthermore, this tyrosine phosphorylated form of HK1 has an extracellular domain and HK1 is localized to both the head and flagellum of nonpermeabilized cells (Visconti et al., 1995c). We have characterized HK1 in mature sperm from sterile tw32/tw5 mice (mutant sperm) that have defects in motility and sperm-egg interaction (Johnson et al., 1995: Dev Biol 168:138-149). Immunoprecipitation of mouse sperm extracts with an antiserum made against purified rat brain HK1 demonstrates the presence of HK1 in mutant sperm. Various biochemical and immunofluorescence assays indicate that at least a portion of the HK1 present in these cells is an integral membrane protein with an extracellular domain located on the sperm head and flagellum. However, immunoblot analysis with anti-phoshotyrosine antibodies demonstrates that HK1 in mutant sperm is not tyrosine phosphorylated. Northern blot and RT-PCR analysis does not indicate any obvious abnormalities in the transcription of somatic or germ cell-specific HK1 isoforms in mutant testes, and RFLP analysis of recombinant mice indicates that no genes specifying HK1 isoforms are located on chromosome 17. We have mapped the locus responsible for the lack of tyrosine phosphorylation of HK1 mutant sperm to the most proximal (to the centromere) of the four inversions within the t haplotype. A male sterility factor is located in this same inversion (Lyon, 1986: Cell 44:357-363). Since the mutant sperm are unable to complete fertilization, there could be a relationship between sterility and the lack of tyrosine phosphorylation of HK1 in these mutant sperm.

The cellular basis for interaction of sterility factors in the mouse t haplotype.

The t haplotypes are variant forms of the proximal one-third of chromosome 17 in the mouse. They contain four inversions (relative to the wildtype DNA) extending over most of this region and house a number of male sterility factors. Males carrying two complete t haplotypes (t/t) are sterile, as are males homozygous for S2, the sterility factor located in the most distal (relative to the centromere) inversion. Males homozygous for the sterility factor S1, located in the most proximal inversion, are not sterile; however, if such a male also is heterozygous for other sterility factors, then sterility results. It has been suggested therefore that homozygosity for S1 enhances the detrimental action of other sterility factors. Sperm from t/t males have severe motility defects and are unable to penetrate investment-free eggs, while sperm from fertile t/+ mice have less serious motility defects and exhibit a delay in penetration of investment-free eggs. To determine whether homozygosity for S1 enhances the cellular defects exhibited by sperm from mice heterozygous for other sterility factors, we compared the motility and egg-penetrating ability of sperm from fertile mice homozygous for S1 to that of sperm from mice carrying one complete t haplotype and one proximal or distal partial t haplotype. The data suggest that sperm from males carrying a proximal partial t haplotype and a complete t haplotype have serious defects in motility and penetration of the investment-free egg, and support the hypothesis that S1 enhances the detrimental effects of other sterility factors within the t haplotype.

Sperm from mice carrying one or two t haplotypes are deficient in investment and oocyte penetration.

The t haplotypes, mutant forms of the proximal third of mouse chromosome 17 (the t complex), contain factors that contribute to defective sperm function in fertilization. Males carrying two t haplotypes (tx/ty mice) are sterile; their sperm have very poor motility and are unable to penetrate zona-free eggs. Although males carrying one t haplotype (t/+) are fertile, genetic evidence suggests that the sperm carrying the normal form of chromosome 17 (+t) are dysfunctional in fertilization, and some or all sperm have abnormal motility. Some of the same genetic factors that cause sterility in tx/ty males probably contribute to the dysfunction of +t sperm from t/+ males; however, it is unclear which steps in gamete interaction are defective in sperm from t/+ males, or whether the defects are similar to those observed in sperm from tx/ty males. We have developed a unique low sperm:egg ratio IVF assay for sperm function in fertilization. Using this assay, we have shown that tw5/+ sperm are less able than congenic +/+ sperm to penetrate the zona (probably due to their abnormal motility) and to penetrate the zona-free oocyte. Since tw5/tw32 sperm are unable to complete these same two steps in sperm-egg interaction, these specific deficits could be involved in both transmission ratio distortion and sterility. We have also shown that tw5/tw32 sperm are deficient in their ability to bind to the zona and to the oolemma. These results suggest that t haplotypes contain loci which affect a number of sperm functions and thus could be a rich source of genes important for sperm-egg interaction.

The human homolog of a candidate mouse t complex responder gene: conserved motifs and evolution with punctuated equilibria.

The mouse Tcp-10 gene has been established as a molecular candidate for the t complex responder locus which plays a central role in the transmission ratio distortion phenotype expressed by males heterozygous for a t haplotype. Here we describe a comparison of the mouse and human TCP10 coding sequences. The results show that whole exons have been added or eliminated from the transcripts expressed in each species, suggesting an evolutionary process of punctuated equilibria for this gene. Two of the polypeptide regions that are most conserved between the two species contain specific peptide motifs. The conserved C-terminal region contains a unique nonapeptide repeat of unknown function and the conserved N-terminal region contains a pair of leucine zippers within a region that shows additional similarity to the coiled-coil regions of various cytosolic polypeptides. These results are discussed in terms of the possible function of the TCP10 protein.

Factors that may regulate assembly of the mammalian sperm tail deduced from a mouse t complex mutation.

A unique pattern of aberrant sperm development occurs in laboratory mice (Mus domesticus) that have been made homozygous for an allele of an autosomal gene, Hst-6s, derived from another mouse species, Mus spretus. During the abnormal spermiogenic process of these sterile animals, the sperm tail fails to assemble normally, although a bud develops at the site of the centriole in early spermatids. The bud enlarges during sperm development and eventually contains elements of a mature sperm tail. Tubulin assembles primarily into single microtubules rather than doublets. These singlets form a circular array that is not oriented relative to the centriole. While dense fibers form in association with the singlet microtubules, the fibrous sheath components accumulate in a single irregular mass. These observations suggest that microtubule doublets are required for the organization of an axoneme. In addition, while dense fibers can form normally in association with singlet microtubules, the fibrous sheath requires the axoneme as a substrate for normal organization.

Hybrid sterility-6: a mouse t complex locus controlling sperm flagellar assembly and movement.

Mouse t haplotypes alter sperm differentiation, resulting in abnormal sperm movement and sterility. In previous studies, a locus responsible for hybrid sterility in the genus Mus,Hst-4, was mapped to the distal inversion of the t complex on chromosome 17. Here we report the identification and characterization of two additional hybrid sterility loci, Hst-5 and Hst-6, that map to the same inversion. We further show that an abnormality in sperm flagellar curvature deriving from interactions between t haplotypes and the M. spretus allele of Hst-6 is indistinguishable from one exhibited by sperm from mice carrying two t haplotypes. Additionally, we demonstrate that this latter phenotype maps to the distal inversion of t haplotypes. Morphological and functional studies of Hst-6 mutant sperm also imply that the product(s) of Hst-6 is a spermatogenic-specific protein, important for assembly and function of the sperm axoneme. Thus, Hst-6 provides direct access to the molecular basis of t haplotype-specific alterations in sperm function that emanate from the t complex distal inversion.

Localization of the Mas proto-oncogene to a densely marked region of mouse chromosome 17 associated with genomic imprinting.

The mouse homolog of the human proto-oncogene MAS was mapped by two interspecific backcrosses to the proximal portion of MMU17. Higher resolution mapping was accomplished through the analysis of genotypes duplicated or deleted for a megabase-size subregion within MMU17. The results demonstrate a map position for Mas in the close vicinity of Igf2r, which encodes another membrane receptor known to undergo genomic imprinting. The data provide further evidence for the clustering of genes in a 1-Mb region of chromosome 17, with the absence of any identified genes in a nearby region likely to be six times larger.

Production of functional human hemoglobin in transgenic swine.

A construct containing the locus control region (LCR) from the human beta globin locus together with two copies of the human alpha 1 gene and a single copy of the human beta A gene was used to obtain three transgenic pigs. The transgenic pigs are healthy, not anemic, and grow at a rate comparable to non-transgenic littermates. All animals expressed the human genes. However, alpha globin was consistently expressed at higher levels than beta globin. Isolation of the human hemoglobin from both porcine hemoglobin and other non-hemoglobin proteins was accomplished by ion exchange chromatography. The purified porcine derived human hemoglobin exhibited an oxygen affinity similar to that of human derived human hemoglobin.

Concerted evolution of the mouse Tcp-10 gene family: implications for the functional basis of t haplotype transmission ratio distortion.

The mouse Tcr locus is defined by its central role in the transmission ratio distortion phenotype characteristic of t haplotypes. A molecular candidate for Tcr has been identified in the form of a gene--Tcp-10b--expressed during spermatogenesis. Tcp-10b is one member of a multigene family present in two to four copies on different homologs of chromosome 17. The coding regions of the Tcp-10 genes present within two inbred strains were compared with those of the tw5 haplotype. The various gene family members are highly conserved relative to each other with a minimum nucleotide identity of 98.6% in all pairwise comparisons. Maximal parsimony analysis indicates that the Tcp-10 gene family has evolved in a concerted manner with the obliteration of nearly all individual gene-specific characteristics. As a consequence, the candidate for the full-length mutant Tcr gene product is distinguished by only a single, highly conservative, amino acid change. The data are consistent with the hypothesis that the effector of mutant Tcr activity is a second, alternatively spliced product that is expressed in a haploid- and allele-specific manner.

A novel mouse chromosome 17 hybrid sterility locus: implications for the origin of t haplotypes.

The effects of heterospecific combinations of mouse chromosome 17 on male fertility and transmission ratio were investigated through a series of breeding studies. Animals were bred to carry complete chromosome 17 homologs, or portions thereof, from three different sources-Mus domesticus, Mus spretus and t haplotypes. These chromosome 17 combinations were analyzed for fertility within the context of a M. domesticus or M. spretus genetic background. Two new forms of hybrid sterility were identified. First, the heterospecific combination of M. spretus and t haplotype homologs leads to complete male sterility on both M. spretus and M. domesticus genetic backgrounds. This is an example of symmetrical hybrid sterility. Second, the presence of a single M. domesticus chromosome 17 homolog within a M. spretus background causes sterility, however, the same combination of chromosome 17 homologs does not cause sterility within the M. domesticus background. This is a case of asymmetrical hybrid sterility. Through an analysis of recombinant chromosomes, it was possible to map the M. domesticus, M. spretus and t haplotype alleles responsible for these two hybrid sterility phenotypes to the same novel locus (Hybrid sterility-4). Previous structural studies had led to the hypothesis that the ancestral t haplotype originated through an introgression event from M. spretus or a related species. If this were true, one might expect that (1) M. spretus homologs would be transmitted at a non-Mendelian ratio within the M. domesticus background, and (2) t haplotypes would be transmitted at a ratio closer to Mendelian within the M. spretus background.(ABSTRACT TRUNCATED AT 250 WORDS)

Allele- and haploid-specific product generated by alternative splicing from a mouse t complex responder locus candidate.

Mouse t haplotypes represent a variant form of chromosome 17 that has evolved the ability to propagate through natural populations by the phenomenon of 'transmission ratio distortion' (TRD), in which heterozygous +/t males transmit their t-carrying chromosome to 95% or more of their offspring. Although multiple t-associated loci have a role in expression of this phenotype, only one--the t complex responder (Tcr) locus--is responsible for determining which of the two homologues of chromosome 17 will be transmitted at a high ratio. A candidate gene (Tcp-10b) for Tcr that is expressed in both meiotic and post-meiotic male germ cells has been cloned. But for this candidate gene to function as the haploid effector of TRD, the t-allele of this gene (Tcp-10bt) must express a unique product in a haploid-specific manner. Here we show that a change in the splicing pattern of Tcp-10bt transcripts occurs during sperm differentiation. This change results in a unique allele-specific and haploid-specific transcript which could encode a variant polypeptide that would fulfil the conditions required of the Tcr effector of TRD.

A mouse chromosome 17 gene encodes a testes-specific transcript with unusual properties.

We have characterized a novel mouse gene (D17Si11) on chromosome 17 that expresses a major transcript observed uniquely in the testes. The D17Si11 locus has been mapped to the central region of chromosome 17 between H-2 and C3. Sequence analysis demonstrates several unusual features of this locus and its transcript: first is the presence of complementary sets of alternating purine and pyrimidine residues within the 3' region of the transcript that could form double-stranded, hairpin-like secondary structures with properties similar to that of Z-DNA; second is the existence of a hypothetical, long open reading frame in the nucleotide strand that is complementary to the testes transcripts. This complementary strand open reading frame is three times the size of the longest potential open reading frame present in the transcript itself. Although a function for D17Si11 has yet to be determined, the gene is relatively nonpolymorphic in mice and appears conserved in mammals.