Noncoding genes on sex chromosomes and their function in sex determination, dosage compensation, male traits, and diseases
- Maier, Michelle, McInerney, Molly-Rose, Graves, Jennifer, Charchar, Fadi
- Authors: Maier, Michelle , McInerney, Molly-Rose , Graves, Jennifer , Charchar, Fadi
- Date: 2021
- Type: Text , Journal article , Review
- Relation: Sexual Development Vol. 15, no. 5-6 (2021), p. 432-440
- Relation: http://purl.org/au-research/grants/nhmrc/1123472
- Full Text:
- Reviewed:
- Description: The mammalian Y chromosome has evolved in many species into a specialized chromosome that contributes to sex development among other male phenotypes. This function is well studied in terms of protein-coding genes. Less is known about the noncoding genome on the Y chromosome and its contribution to both sex development and other traits. Once considered junk genetic material, noncoding RNAs are now known to contribute to the regulation of gene expression and to play an important role in refining cellular functions. The prime examples are noncoding genes on the X chromosome, which mitigate the differential dosage of genes on sex chromosomes. Here, we discuss the evolution of noncoding RNAs on the Y chromosome and the emerging evidence of how micro, long, and circular noncoding RNAs transcribed from the Y chromosome contribute to sex differentiation. We briefly touch on emerging evidence that these noncoding RNAs also contribute to some other important clinical phenotypes in humans. © 2021 S. Karger AG. All rights reserved.
- Authors: Maier, Michelle , McInerney, Molly-Rose , Graves, Jennifer , Charchar, Fadi
- Date: 2021
- Type: Text , Journal article , Review
- Relation: Sexual Development Vol. 15, no. 5-6 (2021), p. 432-440
- Relation: http://purl.org/au-research/grants/nhmrc/1123472
- Full Text:
- Reviewed:
- Description: The mammalian Y chromosome has evolved in many species into a specialized chromosome that contributes to sex development among other male phenotypes. This function is well studied in terms of protein-coding genes. Less is known about the noncoding genome on the Y chromosome and its contribution to both sex development and other traits. Once considered junk genetic material, noncoding RNAs are now known to contribute to the regulation of gene expression and to play an important role in refining cellular functions. The prime examples are noncoding genes on the X chromosome, which mitigate the differential dosage of genes on sex chromosomes. Here, we discuss the evolution of noncoding RNAs on the Y chromosome and the emerging evidence of how micro, long, and circular noncoding RNAs transcribed from the Y chromosome contribute to sex differentiation. We briefly touch on emerging evidence that these noncoding RNAs also contribute to some other important clinical phenotypes in humans. © 2021 S. Karger AG. All rights reserved.
- Gielen, Marij, Hageman, Geja, Antoniou, Evangelia, Nordfjall, Katarina, Mangino, Massimo, Balasubramanyam, Muthuswamy, De Meyer, Tim de, Hendricks, Audrey, Giltay, Erik, Hunt, Steven, Nettleton, Jennifer, Salpea, Klelia, Diaz, Vanessa, Farzaneh-Far, Ramin, Atzmon, Gil, Harris, Sarah, Hou, Lifang, Gilley, David, Hovatta, Iiris, Kark, Jeremy, Nassar, Hisham, Kurz, David, Mather, Karen, Willeit, Peter, Zheng, Yun-Ling, Pavanello, Sofia, Demerath, Ellen, Rode, Line, Bunout, Daniel, Steptoe, Andrew, Boardman, Lisa, Marti, Amelia, Needham, Belinda, Zheng, Wei, Ramsey-Goldman, Rosalind, Pellatt, Andrew, Kaprio, Jaakko, Hofmann, Jonathan, Gieger, Christian, Paolisso, Giuseppe, Hjelmborg, Jacob, Mirabello, Lisa, Seeman, Teresa, Wong, Jason, Van Der Harst, Pim, Broer, Linda, Kronenberg, Florian, Kollerits, Barbara, Strandberg, Timo, Eisenberg, Dan, Duggan, Catherine, Verhoeven, Josine, Schaakxs, Roxanne, Zannolli, Raffaela, Dos Reis, Rosana, Charchar, Fadi, Tomaszewski, Maciej, Mons, Ute, Demuth, Ilja, Molli, Andrea, Cheng, Guo, Krasnienkov, Dmytro, D'Antono, Bianca, Kasielski, Marek, McDonnell, Barry, Ebstein, Richard, Sundquist, Kristina, Pare, Guillaume, Chong, Michael, Zeegers, Maurice
- Authors: Gielen, Marij , Hageman, Geja , Antoniou, Evangelia , Nordfjall, Katarina , Mangino, Massimo , Balasubramanyam, Muthuswamy , De Meyer, Tim de , Hendricks, Audrey , Giltay, Erik , Hunt, Steven , Nettleton, Jennifer , Salpea, Klelia , Diaz, Vanessa , Farzaneh-Far, Ramin , Atzmon, Gil , Harris, Sarah , Hou, Lifang , Gilley, David , Hovatta, Iiris , Kark, Jeremy , Nassar, Hisham , Kurz, David , Mather, Karen , Willeit, Peter , Zheng, Yun-Ling , Pavanello, Sofia , Demerath, Ellen , Rode, Line , Bunout, Daniel , Steptoe, Andrew , Boardman, Lisa , Marti, Amelia , Needham, Belinda , Zheng, Wei , Ramsey-Goldman, Rosalind , Pellatt, Andrew , Kaprio, Jaakko , Hofmann, Jonathan , Gieger, Christian , Paolisso, Giuseppe , Hjelmborg, Jacob , Mirabello, Lisa , Seeman, Teresa , Wong, Jason , Van Der Harst, Pim , Broer, Linda , Kronenberg, Florian , Kollerits, Barbara , Strandberg, Timo , Eisenberg, Dan , Duggan, Catherine , Verhoeven, Josine , Schaakxs, Roxanne , Zannolli, Raffaela , Dos Reis, Rosana , Charchar, Fadi , Tomaszewski, Maciej , Mons, Ute , Demuth, Ilja , Molli, Andrea , Cheng, Guo , Krasnienkov, Dmytro , D'Antono, Bianca , Kasielski, Marek , McDonnell, Barry , Ebstein, Richard , Sundquist, Kristina , Pare, Guillaume , Chong, Michael , Zeegers, Maurice
- Date: 2018
- Type: Text , Journal article
- Relation: American Journal of Clinical Nutrition Vol. 108, no. 3 (2018), p. 453-475
- Relation: http://purl.org/au-research/grants/nhmrc/1123472
- Full Text: false
- Reviewed:
- Description: Background: Even before the onset of age-related diseases, obesity might be a contributing factor to the cumulative burden of oxidative stress and chronic inflammation throughout the life course. Obesity may therefore contribute to accelerated shortening of telomeres. Consequently, obese persons are more likely to have shorter telomeres, but the association between body mass index (BMI) and leukocyte telomere length (TL) might differ across the life span and between ethnicities and sexes. Objective: A collaborative cross-sectionalmeta-analysis of observational studies was conducted to investigate the associations between BMI and TL across the life span. Design: Eighty-seven distinct study samples were included in the meta-analysis capturing data from 146,114 individuals. Studyspecific age- and sex-adjusted regression coefficients were combined by using a random-effects model in which absolute [base pairs (bp)] and relative telomere to single-copy gene ratio (T/S ratio) TLs were regressed against BMI. Stratified analysis was performed by 3 age categories ("young": 18-60 y; "middle": 61-75 y; and "old": >75 y), sex, and ethnicity. Results: Each unit increase in BMI corresponded to a-3.99 bp (95% CI: -5.17, -2.81 bp) difference in TL in the total pooled sample; among young adults, each unit increase in BMI corresponded to a -7.67 bp (95% CI:-10.03,-5.31 bp) difference. Each unit increase in BMI corresponded to a -1.58 × 10-3 unit T/S ratio (0.16% decrease; 95% CI: -2.14 × 10-3, -1.01 × 10-3) difference in ageand sex-adjusted relative TL in the total pooled sample; among young adults, each unit increase in BMI corresponded to a -2.58 × 10-3 unit T/S ratio (0.26% decrease; 95% CI: -3.92 × 10-3, -1.25 × 10-3). The associations were predominantly for the white pooled population. No sex differences were observed. Conclusions: A higher BMI is associated with shorter telomeres, especially in younger individuals. The presently observed difference is not negligible. Meta-analyses of longitudinal studies evaluating change in body weight alongside change in TL arewarranted.
- «
- ‹
- 1
- ›
- »