The small GTPase Rheb is required for spermatogenesis but not oogenesis.

The process of germ cell development is under the tight control of various signaling pathways, among which the PI3K-Akt-mTOR pathway is of critical importance. Previous studies have demonstrated sex-specific roles for several components of this pathway. In the current study, we aimed to evaluate the role of Rheb, a member of the small GTPase superfamily and a critical component for mTORC1 activation, in male and female gametogenesis. The function of Rheb in development and the nervous system has been extensively studied, but little is known about its role in the germ line. We have exploited genetic approaches in the mouse to study the role of Rheb in the germ line and have identified an essential role in spermatogenesis. Conditional knockout (cKO) of Rheb in the male germ line resulted in severe oligoasthenoteratozoospermia and male sterility. More detailed phenotypic analyses uncovered an age-dependent meiotic progression defect combined with subsequent abnormalities in spermiogenesis as evidenced by abnormal sperm morphology. In the female, however, germ-cell specific inactivation of Rheb was not associated with any discernible abnormality; these cKO mice were fertile with morphologically unremarkable ovaries, normal primordial follicle formation, and subsequent follicle maturation. The absence of an abnormal ovarian phenotype is striking given previous studies demonstrating a critical role for the mTORC1 pathway in the maintenance of primordial follicle pool. In conclusion, our findings demonstrate an essential role of Rheb in diverse aspects of spermatogenesis but suggest the existence of functionally redundant factors that can compensate for Rheb deficiency within oocytes.

Event-by-event fluctuations of azimuthal particle anisotropy in Au+Au collisions at square root(sNN) = 200 GeV.

This Letter presents the first measurement of event-by-event fluctuations of the elliptic flow parameter v(2) in Au+Au collisions at square root(s(NN))=200 GeV as a function of collision centrality. The relative nonstatistical fluctuations of the v(2) parameter are found to be approximately 40%. The results, including contributions from event-by-event elliptic flow fluctuations and from azimuthal correlations that are unrelated to the reaction plane (nonflow correlations), establish an upper limit on the magnitude of underlying elliptic flow fluctuations. This limit is consistent with predictions based on spatial fluctuations of the participating nucleons in the initial nuclear overlap region. These results provide important constraints on models of the initial state and hydrodynamic evolution of relativistic heavy ion collisions.

High transverse momentum triggered correlations over a large pseudorapidity acceptance in Au + Au collisions at square root(s(NN)) = 200 GeV.

A measurement of two-particle correlations with a high transverse momentum trigger particle (p(T)(trig) > 2.5 GeV/c) is presented for Au+Au collisions at square root(s(NN)) = 200 GeV over the uniquely broad longitudinal acceptance of the PHOBOS detector (-4 < Delta eta < 2). A broadening of the away-side azimuthal correlation compared to elementary collisions is observed at all Delta eta. As in p+p collisions, the near side is characterized by a peak of correlated partners at small angle relative to the trigger particle. However, in central Au+Au collisions an additional correlation extended in Delta eta and known as the "ridge" is found to reach at least |Delta eta| approximately = 4. The ridge yield is largely independent of Delta eta over the measured range, and it decreases towards more peripheral collisions. For the chosen (p(T)(trig) cut, the ridge yield is consistent with zero for events with less than roughly 100 participating nucleons.

Sacroplasty versus vertebroplasty: comparable clinical outcomes for the treatment of fracture-related pain.

BACKGROUND AND PURPOSE: Little is known about the long-term clinical outcomes of sacroplasty, a relatively new minimally invasive percutaneous procedure for the treatment of sacral insufficiency fractures. The first purpose of the present study, therefore, was to investigate the effects of sacroplasty on pain, mobility, and activities of daily living (ADLs). A second purpose was to compare clinical outcomes of sacroplasty with those of vertebroplasty, a similar but more established procedure. MATERIALS AND METHODS: A retrospective case series of 12 patients who had a sacroplasty and a control group of 21 patients who had undergone a vertebroplasty was conducted. A 12-item questionnaire and subsequent telephone interview requested each patient to rate the intensity of pain, as well as the ability to ambulate and perform ADLs, before sacroplasty or vertebroplasty, and at the time of the interview. RESULTS: There was a statistically significant decrease in overall self-reported pain, as well as an increase in self-reported ability to ambulate and perform ADLs after sacroplasty or vertebroplasty. These improvements were equivalent, regardless of which procedure the patient received. CONCLUSION: The present study suggests that the treatment of sacral insufficiency fractures with sacroplasty produces relatively long-lasting improvements in pain, mobility, and the ability to perform ADLs. These data also suggest that the clinical outcomes of sacroplasty are comparable with those of vertebroplasty, an accepted and more routinely performed procedure.

High-frequency homologous recombination between duplicate chromosomal immunoglobulin mu heavy-chain constant regions.

Homologous recombination was used in a previous study to correct a 2-base-pair deletion in the third constant domain (Cmu3) of the haploid chromosomal mu gene in a mutant hybridoma cell line by transfer of a pSV2neo vector bearing a subfragment of the normal Cmu region (M.D. Baker, N. Pennell, L. Bosnoyan, and M.J. Shulman, Proc. Natl. Acad. Sci. USA 85:6432-6436, 1988). In these experiments, both gene replacement and single reciprocal crossover events were found to restore normal, cytolytic 2,4,6-trinitrophenyl-specific immunoglobulin M production to the mutant cells. In the cases of single reciprocal recombination, the structure of the recombinant mu gene is such that the normal Cmu region, in its correct position 3' of the expressed 2,4,6-trinitrophenyl-specific heavy-chain variable region, is separated from the mutant Cmu region by the integrated vector sequences. I report here that homologous recombination occurs with high frequency between the duplicate Cmu regions in mitotically growing hybridoma cells. The homologous recombination events were easily detected since they generated hybridomas that were phenotypically different from the parental cells. Analysis of the recombinant cells suggests that gene conversion is the most frequent event, occurring between 60 and 73% of the time. The remaining events consisted of single reciprocal crossovers. Intrachromatid double reciprocal recombination was not detected. The high frequency of recombination, the ability to isolate and analyze the participants in the recombination reactions, and the capacity to generate specific modifications in the immunoglobulin Cmu regions by gene targeting suggest that this system will be useful for studying mammalian chromosomal homologous recombination. Moreover, the ability to specifically modify the chromosomal immunoglobulin genes by homologous recombination should facilitate studies of immunoglobulin gene regulation and expression and provide a more convenient of engineering specifically modified antibody.

High-frequency gene conversion between repeated C mu sequences integrated at the chromosomal immunoglobulin mu locus in mouse hybridoma cells.

The occurrence of mitotic recombination between repeated immunoglobulin mu gene constant (C mu) region sequences stably integrated at the haploid chromosomal immunoglobulin mu locus in murine hybridoma cells was investigated. Recombination events are detected as changes in hapten-specific immunoglobulin M production. Recombination occurs with high frequency (0.5 to 0.8%) by a mechanism consistent with gene conversion. A double-strand break repair-like mechanism is suggested by the finding that repair of a 2-bp deletion mutation and a 2-bp insertion mutation occurs with parity in a donor-directed manner. The results also suggest that the gene conversion process is directional in that the 5' C mu region sequence is preferentially converted.

Ectopic recombination within homologous immunoglobulin mu gene constant regions in a mouse hybridoma cell line.

We have transferred a pSV2neo vector containing the wild-type constant region of the immunoglobulin mu gene (C mu) into the mutant hybridoma igm482, which bears a 2-bp deletion in the third constant-region exon of its haploid chromosomal mu gene (C mu 3). Independent igm482 transformants contain the wild-type immunoglobulin C mu region stably integrated in ectopic chromosomal positions. We report here that the wild-type immunoglobulin C mu region can function as the donor sequence in a gene conversion event which corrects the 2-bp deletion in the mutant igm482 chromosomal C mu 3 exon. The homologous recombination event restores normal immunoglobulin M production in the mutant cell.

Homologous recombination between transferred and chromosomal immunoglobulin kappa genes.

Homologous recombination between transferred and chromosomal DNAs provides a means of introducing well-defined, predetermined changes in the chromosomal genes. Here we report that this approach can be used to specifically modify the immunoglobulin genes in mouse hybridoma cells. The test system is based on the Sp6 hybridoma, which synthesizes immunoglobulin M (kappa) specific for the hapten 2,4,6-trinitrophenyl (TNP). As recipient cells, we used the Sp6-derived mutant hybridoma igk14, which has a deletion of the kappa TNP gene and consequently does not synthesize TNP-specific immunoglobulin M. igk14 retains the mu TNP gene and two additional rearranged kappa genes, denoted kappa M21B1 and kappa M21G. As a transfer vector, we used pSV2neo bearing the functionally rearranged TNP-specific V kappa segment. Following DNA transfer by electroporation, we isolated rare transformants which produced normal amounts of the functional kappa TNP chain. Analysis of the DNA of these transformants indicated that in all cases, a functional kappa TNP gene had been formed as the result of a homologous integrative recombination event with the igk14 kappa M21B1 gene. These results suggest that homologous recombination might be used for mapping and introducing immunoglobulin gene mutations and for more conveniently engineering specifically altered immunoglobulins.

Evidence for biased holliday junction cleavage and mismatch repair directed by junction cuts during double-strand-break repair in mammalian cells.

In mammalian cells, several features of the way homologous recombination occurs between transferred and chromosomal DNA are consistent with the double-strand-break repair (DSBR) model of recombination. In this study, we examined the segregation patterns of small palindrome markers, which frequently escape mismatch repair when encompassed within heteroduplex DNA formed in vivo during mammalian homologous recombination, to test predictions of the DSBR model, in particular as they relate to the mechanism of crossover resolution. According to the canonical DSBR model, crossover between the vector and chromosome results from cleavage of the joint molecule in two alternate sense modes. The two crossover modes lead to different predicted marker configurations in the recombinants, and assuming no bias in the mode of Holliday junction cleavage, the two types of recombinants are expected in equal frequency. However, we propose a revision to the canonical model, as our results suggest that the mode of crossover resolution is biased in favor of cutting the DNA strands upon which DNA synthesis is occurring during formation of the joint molecule. The bias in junction resolution permitted us to examine the potential consequences of mismatch repair acting on the DNA breaks generated by junction cutting. The combination of biased junction resolution with both early and late rounds of mismatch repair can explain the marker patterns in the recombinants.

The mechanism of mammalian gene replacement is consistent with the formation of long regions of heteroduplex DNA associated with two crossing-over events.

In this study, the mechanism of mammalian gene replacement was investigated. The system is based on detecting homologous recombination between transferred vector DNA and the haploid, chromosomal immunoglobulin mu-delta region in a murine hybridoma cell line. The backbone of the gene replacement vector (pCmuCdeltapal) consists of pSV2neo sequences bounded on one side by homology to the mu gene constant (Cmu) region and on the other side by homology to the delta gene constant (Cdelta) region. The Cmu and Cdelta flanking arms of homology were marked by insertions of an identical 30-bp palindrome which frequently escapes mismatch repair when in heteroduplex DNA (hDNA). As a result, intermediates bearing unrepaired hDNA generate mixed (sectored) recombinants following DNA replication and cell division. To monitor the presence and position of sectored sites and, hence, hDNA formation during the recombination process, the palindrome contained a unique NotI site that replaced an endogenous restriction enzyme site at each marker position in the vector-borne Cmu and Cdelta regions. Gene replacement was studied under conditions which permitted the efficient recovery of the product(s) of individual recombination events. Analysis of marker segregation patterns in independent recombinants revealed that extensive hDNA was formed within the Cmu and Cdelta regions. In several recombinants, palindrome markers in the Cmu and Cdelta regions resided on opposite DNA strands (trans configuration). These results are consistent with the mammalian gene replacement reaction involving two crossing-over events in homologous flanking DNA.

Requirements for ectopic homologous recombination in mammalian somatic cells.

Ectopic recombination occurs between DNA sequences that are not in equivalent positions on homologous chromosomes and has beneficial as well as potentially deleterious consequences for the eukaryotic genome. In the present study, we have examined ectopic recombination in mammalian somatic (murine hybridoma) cells in which a deletion in the mu gene constant (Cmu) region of the endogenous chromosomal immunoglobulin mu gene is corrected by using as a donor an ectopic wild-type Cmu region. Ectopic recombination restores normal immunoglobulin M production in hybridomas. We show that (i) chromosomal mu gene deletions of 600 bp and 4 kb are corrected less efficiently than a deletion of only 2 bp, (ii) the minimum amount of homology required to mediate ectopic recombination is between 1.9 and 4.3 kb, (iii) the frequency of ectopic recombination does not depend on donor copy number, and (iv) the frequency of ectopic recombination in hybridoma lines in which the donor and recipient Cmu regions are physically connected to each other on the same chromosome can be as much as 4 orders of magnitude higher than it is for the same sequences located on homologous or nonhomologous chromosomes. The results are discussed in terms of a model for ectopic recombination in mammalian somatic cells in which the scanning mechanism that is used to locate a homologous partner operates preferentially in cis.

Axonal flip-flops and oscillators.

The strange and unpleasant sensations (paraesthesiae) or asynchronous motor-unit activation (fasciculation) that result from a period of limb ischaemia are examples of ectopic discharge in peripheral nerves. Ectopic activity also results from demyelination and is associated with serious neurological conditions, such as multiple sclerosis. A build-up of extracellular K(+) in the internode and persistent Na(+) currents are now implicated in generating the different forms of activity arising in normal and demyelinated axons.

Involvement of Na+ channels in pain pathways.

Voltage-dependent Na+ channels in sensory nerves contribute to the control of membrane excitability and underlie action potential generation. Na+ channel subtypes exhibit a neurone-specific and developmentally regulated pattern of expression, and changes in both channel expression and function are caused by disease. Recent evidence implicates specific roles for Na+ channel subtypes Na(v)1.3 and Na(v)1.8 in pain states that are associated with nerve injury and inflammation, respectively. Insight into the role of Na(v)1.8 in pain pathways has been gained by the generation of a null mutant. Although drugs discriminate poorly between subtypes, the molecular diversity of channels and subtype-specific modulation might provide opportunities to target pain pathways selectively.

Formation and repair of heteroduplex DNA on both sides of the double-strand break during mammalian gene targeting.

In this study, we examined homologous recombination in mammalian cells using a gene targeting assay in which the introduction of a double-strand-break (DSB) in the vector-borne region of homology to the chromosome resulted in targeted vector integration. The vector-borne DSB was flanked with small palindromic insertions that, when encompassed within heteroduplex DNA (hDNA) formed during targeted vector integration, were capable of avoiding the activity of the mismatch repair (MMR) system. When used in conjunction with an isolation procedure in which the product(s) of each targeted vector integration event were retained for molecular analysis, information about recombination mechanisms was obtained. The examination of marker segregation patterns in independent recombinants revealed the following, (i) hDNA tracts could form simultaneously on each side of the DSB and in both participating homologous regions. Clonal analysis of sectored recombinants revealed that, in the homologous repeats generated by the recombination event, vector-borne palindrome and chromosomal markers were linked in the expected way in each strand of the hDNA intermediate, (ii) hDNA tracts were subject to MMR processing that occurred on opposite sides of the DSB, and (iii) in the majority of recombinants, the vector-borne marker was replaced with the corresponding marker from the chromosome. Bidirectional hDNA formation and MMR processing of both sides of the DSB are consistent with the double-strand-break repair (DSBR) model of recombination.

Use of a small palindrome genetic marker to investigate mechanisms of double-strand-break repair in mammalian cells.

We examined mechanisms of mammalian homologous recombination using a gene targeting assay in which the vector-borne region of homology to the chromosome bore small palindrome insertions that frequently escape mismatch repair when encompassed within heteroduplex DNA (hDNA). Our assay permitted the product(s) of each independent recombination event to be recovered for molecular analysis. The results revealed the following: (i) vector-borne double-strand break (DSB) processing usually did not yield a large double-strand gap (DSG); (ii) in 43% of the recombinants, the results were consistent with crossover at or near the DSB; and (iii) in the remaining recombinants, hDNA was an intermediate. The sectored (mixed) genotypes observed in 38% of the recombinants provided direct evidence for involvement of hDNA, while indirect evidence was obtained from the patterns of mismatch repair (MMR). Individual hDNA tracts were either long or short and asymmetric or symmetric on the one side of the DSB examined. Clonal analysis of the sectored recombinants revealed how vector-borne and chromosomal markers were linked in each strand of individual hDNA intermediates. As expected, vector-borne and chromosomal markers usually resided on opposite strands. However, in one recombinant, they were linked on the same strand. The results are discussed with particular reference to the double-strand-break repair (DSBR) model of recombination.

Mechanisms involved in targeted gene replacement in mammalian cells.

The "ends-out" or omega (Omega)-form gene replacement vector is used routinely to perform targeted genome modification in a variety of species and has the potential to be an effective vehicle for gene therapy. However, in mammalian cells, the frequency of this reaction is low and the mechanism unknown. Understanding molecular features associated with gene replacement is important and may lead to an increase in the efficiency of the process. In this study, we investigated gene replacement in mammalian cells using a powerful assay system that permits efficient recovery of the product(s) of individual recombination events at the haploid, chromosomal mu-delta locus in a murine hybridoma cell line. The results showed that (i) heteroduplex DNA (hDNA) is formed during mammalian gene replacement; (ii) mismatches in hDNA are usually efficiently repaired before DNA replication and cell division; (iii) the gene replacement reaction occurs with fidelity; (iv) the presence of multiple markers in one homologous flanking arm in the replacement vector did not affect the efficiency of gene replacement; and (v) in comparison to a genomic fragment bearing contiguous homology to the chromosomal target, gene targeting was only slightly inhibited by internal heterology (pSV2neo sequences) in the replacement vector.

Mechanisms of double-strand-break repair during gene targeting in mammalian cells.

In the present study, the mechanism of double-strand-break (DSB) repair during gene targeting at the chromosomal immunoglobulin mu-locus in a murine hybridoma was examined. The gene-targeting assay utilized specially designed insertion vectors genetically marked in the region of homology to the chromosomal mu-locus by six diagnostic restriction enzyme site markers. The restriction enzyme markers permitted the contribution of vector-borne and chromosomal mu-sequences in the recombinant product to be determined. The use of the insertion vectors in conjunction with a plating procedure in which individual integrative homologous recombination events were retained for analysis revealed several important features about the mammalian DSB repair process:The presence of the markers within the region of shared homology did not affect the efficiency of gene targeting. In the majority of recombinants, the vector-borne marker proximal to the DSB was absent, being replaced with the corresponding chromosomal restriction enzyme site. This result is consistent with either formation and repair of a vector-borne gap or an "end" bias in mismatch repair of heteroduplex DNA (hDNA) that favored the chromosomal sequence. Formation of hDNA was frequently associated with gene targeting and, in most cases, began approximately 645 bp from the DSB and could encompass a distance of at least 1469 bp. The hDNA was efficiently repaired prior to DNA replication. The repair of adjacent mismatches in hDNA occurred predominantly on the same strand, suggesting the involvement of a long-patch repair mechanism.

The molecular basis of multiple vector insertion by gene targeting in mammalian cells.

Gene targeting using sequence insertion vectors generally results in integration of one copy of the targeting vector generating a tandem duplication of the cognate chromosomal region of homology. However, occasionally the target locus is found to contain >1 copy of the integrated vector. The mechanism by which the latter recombinants arise is not known. In the present study, we investigated the molecular basis by which multiple vectors become integrated at the chromosomal immunoglobulin mu locus in a murine hybridoma. To accomplish this, specially designed insertion vectors were constructed that included six diagnostic restriction enzyme markers in the Cmu region of homology to the target chromosomal mu locus. This enabled contributions by the vector-borne and chromosomal Cmu sequences at the recombinant locus to be ascertained. Targeted recombinants were isolated and analyzed to determine the number of vector copies integrated at the chromosomal immunoglobulin mu locus. Targeted recombinants identified as bearing >1 copy of the integrated vector resulted from a Cmu triplication formed by two vector copies in tandem. Examination of the fate of the Cmu region markers suggested that this class of recombinant was generated predominantly, if not exclusively, by two targeted vector integration events, each involving insertion of a single copy of the vector. Both vector insertion events into the chromosomal mu locus were consistent with the double-strand-break repair mechanism of homologous recombination. We interpret our results, taken together, to mean that a proportion of recipient cells is in a predetermined state that is amenable to targeted but not random vector integration.

Intrachromosomal recombination between well-separated, homologous sequences in mammalian cells.

In the present study, we investigated intrachromosomal homologous recombination in a murine hybridoma in which the recipient for recombination, the haploid, endogenous chromosomal immunoglobulin mu-gene bearing a mutation in the constant (Cmu) region, was separated from the integrated single copy wild-type donor Cmu region by approximately 1 Mb along the hybridoma chromosome. Homologous recombination between the donor and recipient Cmu region occurred with high frequency, correcting the mutant chromosomal mu-gene in the hybridoma. This enabled recombinant hybridomas to synthesize normal IgM and to be detected as plaque-forming cells (PFC). Characterization of the recombinants revealed that they could be placed into three distinct classes. The generation of the class I recombinants was consistent with a simple unequal sister chromatid exchange (USCE) between the donor and recipient Cmu region, as they contained the three Cmu-bearing fragments expected from this recombination, the original donor Cmu region along with both products of the single reciprocal crossover. However, a simple mechanism of homologous recombination was not sufficient in explaining the more complex Cmu region structures characterizing the class II and class III recombinants. To explain these recombinants, a model is proposed in which unequal pairing between the donor and recipient Cmu regions located on sister chromatids resulted in two crossover events. One crossover resulted in the deletion of sequences from one chromatid forming a DNA circle, which then integrated into the sister chromatid by a second reciprocal crossover.

Individual and combined effects of relaxin, estrogen, and progesterone in ovariectomized gilts. I. Effects on the growth, softening, and histological properties of the cervix.

Marked growth and softening of the uterine portion of the cervix occur during the last third of the 115-day gestation period in the gilt. These changes in the cervix are temporally correlated with elevated blood levels of relaxin, estrogen, and progesterone. We recently demonstrated that relaxin plays a major role in promoting both the growth and softening of the cervix that occur in pregnant gilts. The roles of estrogen and progesterone in these cervical changes remain poorly understood. Accordingly, this study determined the influence of relaxin, estrogen, and progesterone, individually and in combination, on cervical growth and softening in gilts. Fifteen days after ovariectomy, six to nine nonpregnant, sexually mature gilts were assigned to one of the following eight treatment groups: ovariectomized controls, relaxin treated, estrogen treated, progesterone treated, estrogen plus relaxin treated, progesterone plus relaxin treated, estrogen plus progesterone treated, and progesterone plus estrogen plus relaxin treated. Treatment was given for 10 days, with doses of relaxin (0.5 mg, four times daily), estradiol benzoate (1 mg, twice daily), and progesterone (50 mg, twice daily) selected to provide blood levels resembling those between days 100-110 of gestation. The growth, softening, and histological characteristics of the cervices were determined. Treatment with relaxin significantly increased the growth and softening and altered the histological characteristics of the uterine portion of the cervix in the absence of steroid treatment. Estrogen treatment alone increased cervical growth, but when given in combination with relaxin, estrogen did not augment relaxin's ability to increase either cervical growth or softening. Progesterone alone had little or no effect on the growth or softening of the uterine portion of the cervix. Unexpectedly, when given in combination with relaxin, progesterone augmented markedly relaxin's effects on softening and alteration of the histological characteristics of the cervix. In conclusion, this study is consistent with recent reports that relaxin promotes both the growth and softening of the cervix in the pig. Additionally, this study provides evidence that estrogen and relaxin act independently to promote the growth of the cervix in gilts, whereas progesterone acts in concert with relaxin to promote softening of the cervix and a reduction in the organization and density of cervical collagen fibers. This study provides evidence that relaxin, estrogen, and progesterone all very likely play important roles in the modifications of the cervix that occur during late pregnancy in the gilt.