scholarly journals Haploid selection drives new gene male germline expression

2019 ◽  
Vol 29 (7) ◽  
pp. 1115-1122 ◽  
Author(s):  
Julia B. Raices ◽  
Paulo A. Otto ◽  
Maria D. Vibranovski
Keyword(s):  
Male Germline ◽  
Germline Expression ◽  
New Gene ◽  
Haploid Selection

scholarly journals Human Asunder promotes dynein recruitment and centrosomal tethering to the nucleus at mitotic entry

2012 ◽  
Vol 23 (24) ◽  
pp. 4713-4724 ◽  
Author(s):  
Jeanne N. Jodoin ◽  
Mohammad Shboul ◽  
Poojitha Sitaram ◽  
Hala Zein-Sabatto ◽  
Bruno Reversade ◽  
...  
Keyword(s):  
Male Meiosis ◽  
Human Cells ◽  
Nuclear Pore ◽  
Nuclear Pore Complexes ◽  
Nuclear Surface ◽  
Mitotic Entry ◽  
Male Germline ◽  
Germline Expression ◽  
Cultured Human Cells ◽  
Pore Complexes

Recruitment of dynein motors to the nuclear surface is an essential step for nucleus–centrosome coupling in prophase. In cultured human cells, this dynein pool is anchored to nuclear pore complexes through RanBP2–Bicaudal D2 (BICD2) and Nup133– centromere protein F (CENP-F) networks. We previously reported that the asunder (asun) gene is required in Drosophila spermatocytes for perinuclear dynein localization and nucleus–centrosome coupling at G2/M of male meiosis. We show here that male germline expression of mammalian Asunder (ASUN) protein rescues asun flies, demonstrating evolutionary conservation of function. In cultured human cells, we find that ASUN down-regulation causes reduction of perinuclear dynein in prophase of mitosis. Additional defects after loss of ASUN include nucleus–centrosome uncoupling, abnormal spindles, and multinucleation. Coimmunoprecipitation and overlapping localization patterns of ASUN and lissencephaly 1 (LIS1), a dynein adaptor, suggest that ASUN interacts with dynein in the cytoplasm via LIS1. Our data indicate that ASUN controls dynein localization via a mechanism distinct from that of either BICD2 or CENP-F. We present a model in which ASUN promotes perinuclear enrichment of dynein at G2/M that facilitates BICD2- and CENP-F-mediated anchoring of dynein to nuclear pore complexes.

scholarly journals Recombination and disjunction in female germ cells of Drosophila depend on the germline activity of the gene sex-lethal

Development ◽  
1999 ◽  
Vol 126 (24) ◽  
pp. 5785-5794 ◽  
Author(s):  
D. Bopp ◽  
C. Schutt ◽  
J. Puro ◽  
H. Huang ◽  
R. Nothiger
Keyword(s):  
Ectopic Expression ◽  
Common Mechanism ◽  
Germline Development ◽  
Homologous Chromosomes ◽  
Male Germline ◽  
High Incidence ◽  
Germline Expression ◽  
Sex Lethal ◽  
Female Specific ◽  
Dominant Suppressor

Gametogenesis in males and females differs in many ways. An important difference in Drosophila is that recombination between homologous chromosomes occurs only in female meiosis. Here, we report that this process relies on the correct functioning of Sex-lethal (Sxl) which is primarily known as the master gene in somatic sex determination. Certain alleles of this gene (Sxl(fs)) disrupt the germline, but not the somatic function of Sxl and cause an arrest of germ cell development during cystocyte proliferation. Using dominant suppressor mutations that relieve this early block in Sxl(fs) mutant females, we discovered additional requirements of Sxl for normal meiotic differentiation of the oocyte. Females mutant for Sxl(fs) and carrying a suppressor become fertile, but pairing of homologous chromosomes and formation of chiasmata is severely perturbed, resulting in an almost complete lack of recombinants and a high incidence of non-disjunction events. Similar results were obtained when germline expression of wild-type Sxl was compromised by mutations in virilizer (vir), a positive regulator of Sxl. Ectopic expression of a Sxl transgene in premeiotic stages of male germline development, on the other hand, is not sufficient to allow recombination to take place, which suggests that Sxl does not have a discriminatory role in this female-specific process. We propose that Sxl performs at least two tasks in oogenesis: an ‘early’ function in formation of the egg chamber, and a ‘late’ function in progression of the meiotic cell cycle, suggesting that both events are coordinated by a common mechanism.

scholarly journals Long first exons and epigenetic marks distinguish conserved pachytene piRNA clusters from other mammalian genes

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Tianxiong Yu ◽  
Kaili Fan ◽  
Deniz M. Özata ◽  
Gen Zhang ◽  
Yu Fu ◽  
...  
Keyword(s):  
Rna Polymerase Ii ◽  
Nuclear Export ◽  
Transcriptional Elongation ◽  
Male Germline ◽  
Evolutionarily Conserved ◽  
Germline Expression ◽  
Mammalian Genes ◽  
Multiple Species ◽  
Cg Dinucleotides ◽  
Exon 10

AbstractIn the male germ cells of placental mammals, 26–30-nt-long PIWI-interacting RNAs (piRNAs) emerge when spermatocytes enter the pachytene phase of meiosis. In mice, pachytene piRNAs derive from ~100 discrete autosomal loci that produce canonical RNA polymerase II transcripts. These piRNA clusters bear 5′ caps and 3′ poly(A) tails, and often contain introns that are removed before nuclear export and processing into piRNAs. What marks pachytene piRNA clusters to produce piRNAs, and what confines their expression to the germline? We report that an unusually long first exon (≥ 10 kb) or a long, unspliced transcript correlates with germline-specific transcription and piRNA production. Our integrative analysis of transcriptome, piRNA, and epigenome datasets across multiple species reveals that a long first exon is an evolutionarily conserved feature of pachytene piRNA clusters. Furthermore, a highly methylated promoter, often containing a low or intermediate level of CG dinucleotides, correlates with germline expression and somatic silencing of pachytene piRNA clusters. Pachytene piRNA precursor transcripts bind THOC1 and THOC2, THO complex subunits known to promote transcriptional elongation and mRNA nuclear export. Together, these features may explain why the major sources of pachytene piRNA clusters specifically generate these unique small RNAs in the male germline of placental mammals.

scholarly journals On the origin and evolution of Drosophila new genes during spermatogenesis

2021 ◽  
Author(s):  
Qianwei Su ◽  
Huangyi He ◽  
Qi Zhou
Keyword(s):  
X Chromosome ◽  
Sex Chromosome ◽  
Origin And Evolution ◽  
Functional Studies ◽  
New Genes ◽  
Male Germline ◽  
New Gene ◽  
Direct Cell ◽  
Cell Transcriptome ◽  
Single Cell Transcriptome

Origin of functional new genes is a basic biological process that has a significant contribution to organismal diversity. Previous studies in both Drosophila and mammals showed that new genes tend to be expressed in testis, and avoid the X chromosome presumably because meitoic sex chromosome inactivation (MSCI). Here we analyse the published single-cell transcriptome data of Drosophila adult testis and find an enrichment of male germline mitotic genes, but an underrepresentation of meiotic genes on the X chromosome. This can be attributed to an excess of autosomal meiotic genes that were derived from their X-linked mitotic progenitors, which provides direct cell-level evidence for MSCI in Drosophila. We reveal that new genes, particularly those produced by retrotransposition, tend to exhibit an expression shift toward late spermatogenesis compared to their parental copies, probably due to more intensive sperm competition or sexual conflict. Our results dissect the complex factors including the age, the origination mechanisms and the chromosomal locations that influence the new gene origination and evolution in testis, and identify new gene cases that show divergent expression pattern from their progenitors for future functional studies.

scholarly journals stand still, a Drosophila Gene Involved in the Female Germline for Proper Survival, Sex Determination and Differentiation

Genetics ◽  
1997 ◽  
Vol 145 (4) ◽  
pp. 975-987
Author(s):  
Giuseppa Pennetta ◽  
Daniel Pauli
Keyword(s):  
Sex Determination ◽  
Germ Cells ◽  
Loss Of Function ◽  
Germline Development ◽  
Survival Sex ◽  
Male Germline ◽  
New Gene ◽  
Mutant Phenotypes ◽  
Female Germline ◽  
Novel Protein

We identified a new gene, stand still (stil), required in the female germline for proper survival, sex determination and differentiation. Three strong loss-of-function alleles were isolated. The strongest phenotype exhibited by ovaries dissected from adult females is the complete absence of germ cells. In other ovaries, the few surviving germ cells frequently show a morphology typical of primary spermatocytes. stil is not required either for fly viability or for male germline development. The gene was cloned and found to encode a novel protein. stil is strongly expressed in the female germ cells. Using P[stil  +] transgenes, we show that stil and a closely localized gene are involved in the modification of the ovarian phenotypes of the dominant alleles of ovo caused by heterozygosity of region 49 A-D. The similarity of the mutant phenotypes of stil to that of otu and ovo suggests that the three genes function in a common or in parallel pathways necessary in the female germline for its survival, sex determination and differentiation.

A peek in the micro-sized world: a review of design principles, engineering tools, and applications of engineered microbial community

2020 ◽  
Vol 48 (2) ◽  
pp. 399-409
Author(s):  
Baizhen Gao ◽  
Rushant Sabnis ◽  
Tommaso Costantini ◽  
Robert Jinkerson ◽  
Qing Sun
Keyword(s):  
Microbial Community ◽  
Microbial Communities ◽  
Environmental Remediation ◽  
Real Life ◽  
Design Principles ◽  
Microbial Interactions ◽  
Potential Applications ◽  
New Gene ◽  
Global Biogeochemical Cycles ◽  
Synthetic Microbial Communities

Microbial communities drive diverse processes that impact nearly everything on this planet, from global biogeochemical cycles to human health. Harnessing the power of these microorganisms could provide solutions to many of the challenges that face society. However, naturally occurring microbial communities are not optimized for anthropogenic use. An emerging area of research is focusing on engineering synthetic microbial communities to carry out predefined functions. Microbial community engineers are applying design principles like top-down and bottom-up approaches to create synthetic microbial communities having a myriad of real-life applications in health care, disease prevention, and environmental remediation. Multiple genetic engineering tools and delivery approaches can be used to ‘knock-in' new gene functions into microbial communities. A systematic study of the microbial interactions, community assembling principles, and engineering tools are necessary for us to understand the microbial community and to better utilize them. Continued analysis and effort are required to further the current and potential applications of synthetic microbial communities.

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